Universal surface-mount semiconductor package

ABSTRACT

A variety of footed and leadless semiconductor packages, with either exposed or isolated die pads, are described. Some of the packages have leads with highly coplanar feet that protrude from a plastic body, facilitating mounting the packages on printed circuit boards using wave-soldering techniques.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 14/797,056,now U.S. Pat. No. 9,576,932, filed Jul. 10, 2015. Application Ser. No.14/797,056 is a continuation-in-part of application Ser. No. 14/056,287,now U.S. Pat. No. 9,576,884, filed Oct. 17, 2013, and acontinuation-in-part of application Ser. No. 14/703,359, now U.S. Pat.No. 9,620,439, filed May 4, 2015. Application Ser. No. 14/056,287 claimsthe priority of Provisional Applications Nos. 61/775,540 and 61/775,544,both filed Mar. 9, 2013. Each of the foregoing applications isincorporated herein by reference in its entirety.

FIELD OF THE INVENTION

This invention relates to semiconductor packaging including methods andapparatus designed to fabricate and use surface mount packages inprinted circuit board assembly.

BACKGROUND OF THE INVENTION

Semiconductor devices and ICs are generally contained in semiconductorpackages comprising a protective coating or encapsulant to preventdamage during handling and assembly of the components during shippingand when mounting the components on printed circuit boards. For costreasons, the encapsulant is preferably made of plastic. In a liquidstate, the plastic “mold compound” is injected into a mold chamber at anelevated temperature surrounding the device and its interconnectionsbefore cooling and curing into a solid plastic. Such packages arecommonly referred to as injection molded using a method known as“transfer molding”.

Interconnection to the device is performed through a metallic leadframe,generally of copper, conducting electrical current and heat from thesemiconductor device or “die” into the printed circuit board and itssurroundings. Connections between the die and the leadframe generallycomprise conductive or insulating epoxy to mount the die onto theleadframe's “die pad”, and metallic bond wires, typically gold, copper,or aluminum, to connect the die's surface connections to the leadframe.Alternatively, solder balls, gold bumps, or copper pillars may be usedto attach the topside connections of die directly onto the leadframe.

While the metallic leadframe acts as an electrical and thermal conductorin the finished product, during manufacturing the leadframe temporarilyholds the device elements together until the plastic hardens. Afterplastic curing, the packaged die is separated or “singulated” from otherpackages also formed on the same leadframe by mechanical sawing or bymechanical punching. The saw or punch cuts through the metal leadframeand in some instances through the hardened plastic too.

In “leaded” semiconductor packages, i.e. packages where the metallicleads or “pins” protrude beyond the plastic, the leads are then bentusing mechanical forming to set them into their final shape. In otherinstances the metallic contacts to the semiconductor occur throughconductors only accessible on the underside of the package. Such devicesare known as “leadless” packages. Regardless of leaded or leadlessconstruction, after manufacturing, finished devices are packed into tapeand reels ready for assembly onto customers' printed circuit boards(PCBs).

Leaded Packages One example of a conventional leaded package is shown incross section in FIG. 1A, where a metallic leadframe, typically ofcopper, comprises at least two conductors 1A and 1B electricallyisolated from one another and held together by molded plastic 6.Conductor 1A, the die pad, has semiconductor die 4 mounted on it andattached mechanically and electrically by die attach layer 10 typicallycomprising epoxy, conductive epoxy, or solder. Die pad comprisingconductor 1A then extends outside of molded plastic 6 into a conductivelead mechanically bent to form bent portion 2A and flat portion 3A.Solder 8A, covering flat portion 3A and electrically connectingconductor 1A and semiconductor die 4 to PCB conductive trace 7A formedin PCB 9.

The surface of semiconductor die 4 includes one or more exposedmetallized areas for electrical connections (not shown), electricallyconnected by bond wire 5 and possibly others (not shown), comprisinggold, copper, aluminum or conductive metallic alloys. In this example,bond wire 5 connects a portion of semiconductor die 4 to conductor 1B.Conductor 1B extends laterally outside of molded plastic 6 and throughbent portion 2B and flat portion 3B onto conductive trace 7B in PCB 9.Solder 8B electrically and mechanically connects flat portion 3B ofconductor 1B to PCB conductive trace 7B.

Manufacturing of the device involves mechanically bending leads to formbent portions 2A and 2B such that the bottom of flat portions 3A and 3Bare coplanar for mounting on a flat surface, i.e. PCB 9. Packages withbent leads on two or more package edges are commonly referred to as“gull wing ” packages owing to their curved lead shape. Unfortunately,mechanical processes are imperfect and subject to unavoidablevariability. Attempts to scale gull wing packages to thin dimensions,i.e. to manufacture low profile gull wing packages, fail below 1mmheights because the mechanical variability becomes and intolerablepercentage of the total package height. As such, gull wing packages arenot able to serve the market for thin products and such packages havebeen completely eliminated from cell phone and tablet designs. Otherproducts where gull wing packages persist because of their relativelylow cost are, however, unable to be miniaturized in part because of theminimum height restrictions of gull wing packages.

Aside from issues with scaling gull wing packages to below 0.8 mm forlow profile applications, such IC packages do not normally include athick exposed die pad to act as a heat sink and without special designmodifications are therefore unable to dissipate any significant power orspread heat effectively. Despite its limitation in profile height, poorlead coplanarity, and lack of heat sinking, one advantage of gull wingpackages is their compatibility with low-cost “wave-solder” PCB assemblymethods. Wave-solder based PCB manufacturing is significantly easier andcheaper than reflow assembly used in high tech PCB factories for cellphones and tablets, offering a cost advantage per PCB area of 2× to 4×over reflow assembly. In consumer electronics large PCBs such as thoseused in HDTV backlighting, the PCB cost per board area is a dominanteconomic consideration overriding concerns or the limitations in leadcoplanarity, package height, and power dissipation suffered by gull wingpackages.

Gull wing type packages include small outline or “SO” packages such asthe eight-lead SOP8, the sixteen-lead SOP16, etc.; the three pin smalloutline transistor or “SOT” package such as the SOT23;the thin smalloutline package or TSOP package such as the six-lead TSOP6; the thinsuper small outline package such as the sixteen lead TSSOP16, the quadleaded flat pack such as the 24-lead QFP24, and the low-profile quadleaded flat pack such as the 28 lead LQFP. The term “low-profile” ishistoric as compared to other gull wing packages of the day and stillrequires at least a 2 mm minimum height, i.e. not low profile by today'sstandards for low-profile meaning package heights ranging from 0.4 mm to0.8 mm.

FIG. 1B illustrates the cross section of another type of surface mountpackage unable to scale to thin dimensions. The package, known as thetransistor outline or “TO” type package, is used for power packagesneeded for dissipating and spreading heat from a power semiconductordevice or voltage regulator into a printed circuit board. Popular TOpackages include the leaded TO-220 for through hole mounting and itssurface mount versions, the TO-252 also known as the DPAK, and theTO-263 or D2PAK. Such power packages rely on die pad 1C with an exposedback side as a heatsink in order to achieve heat spreading, improvepackage power dissipation, and lower the package's thermal resistance.Also known as a heat slug, die pad 1C may include an additional heat tab1D extending laterally from die pad 1C beyond molded plastic 6. Powersemiconductor die 4 is attached to die pad 1C using die attach 10 whichgenerally comprises conductive epoxy or solder.

Unlike the previously illustrated integrated circuit package, in powerapplications both current and heat are conducted out of the package fromthe bottom of semiconductor die 4. As such, the backside ofsemiconductor die 4 generally includes a backside metal such as atri-metal sandwich of titanium, nickel and silver or gold to form asolderable backside. The tri-metal sandwich is deposited on the backsideof the die during wafer fabrication after mechanical and chemicalthinning and roughening of the substrate. The roughening is requiredboth for good adherence as well as to insure good ohmic contact, i.e.low contact resistance, between the metal and the semiconductor.

As in the IC package shown in FIG. 1B, the surface of semiconductor die4 includes one or more exposed metallized areas for electricalconnections (not shown), connected electrically to conductive lead 1B bybond wire 5 and possibly others (not shown), comprising gold, copper,aluminum or conductive metallic alloys. In this example, bond wire 5connects a portion of semiconductor die 4 to conductor 1B. Conductor 1Bextends laterally outside of molded plastic 6 and through bent portion2B and flat portion 3B onto conductive trace 7B in PCB 9. Solder 8Belectrically and mechanically connects flat portion 3B of conductor 1Bto PCB conductive trace 7B. Manufacturing of the device involvesmechanically bending leads to form bent portion 2B and others (notshown) such that the bottom of flat portion 3B is coplanar with theexposed bottom surface of die pad 1C for mounting on a flat surface,i.e. PCB 9. Unfortunately, mechanical processes are imperfect andsubject to unavoidable variability, leading to mismatches between thebottom of flat portion 3B and die pad 1C.

In PCB 9 board assembly, solder 8B, typically formed by wave-solderingeasily covers package lead flat portion 3B but as shown by solder 8A isunable to cover heat tab 1D. As a result, a layer of additional solder11 must be place atop PCB conductor 7A before mounting the powerpackage, using wave-soldering. The operation of placing solder onto thePCB is generally performed one package at a time, using pick and placemachines, or in low cost factories, manually, using low-cost factoryworkers. Aside from its poor coplanarity between the bottom of leads andthe back of an exposed die pad and its inability to scale to thinpackage profiles, the need for manual placement of the solder under theheat tab is another disadvantage of conventional surface mount powerpackages.

FIG. 2 illustrates a flow chart of a process for manufacturing leadedsurface mount packages. Both packages start with copper sheet 20. Thewidth of the sheet is matched in width to the machines intended tohandle and process the strip in assembly. The thickness of the copper istypically 200 μm for ICs and 500 μm for power packages. In the case ofICs, as indicated in step 21B, a one side masked etch is optionallyperformed to define the die pad, leads, as well as the leadframe railand tie bars used to hold everything together during processing. In thecase of power packages, as indicated in step 21A, the leadframe must beselectively thinned to distinguish the leads from the thick die pad. Asecond etch is then required to define the die pad, leads, as well asthe leadframe rail and tie bars used to hold everything together duringsubsequent processing. As an alternative process, a punch can be used todefine the die pad, leads and support, then a stamp can be usedselectively to squeeze metal locally to thin it. This mechanicalprocess, while faster than etching, creates several problems. First,compressed metal exhibits mechanical stress not present in etchedleadframes. Stress can lead to cracking of plastic or silicon diecontacting the stressed metal. As a further complication, in leadsmechanically thinned by stamping, the excess metal squeezes out thesides of the thinned lead and must be removed by trimming.

In either case, after the leadframe is etched or mechanically formed,the leadframe is now ready for die attach 22 comprising either epoxy forICs or conductive epoxy or solder for power packages. After die attach(step 22), wire bonding 23A is performed using gold or copper wire forICs and using copper or aluminum wire for power packages. Alternatively,for power devices, after bonding the gate wire in step 23A, the cliplead is attached for the high current connection to the device's topsidein step 23B.

In step 24, leadframe specific molding 24 is performed, meaning eachleadframe requires its own customized leadframe cavity design to insurethe plastic is located only around specific regions containing thesemiconductor, wire bonds and portions of the leadframe, but notcontaining the lead extensions, tie bars and leadframe rails. After theplastic is melted to form the individual packages, deflash operation instep 25 removes excess plastic using mechanical or chemical processes.Next, to enable improved solderability and prevent oxidation of thecopper leadframe, the post-molded copper leadframe is plated with tin,nickel, zinc, or palladium and then chemically etched to remove anyexcess plating material (step 26). Lastly the leads are bent and cut instep 27, separating each packaged die and its corresponding leads fromothers manufactured on the same leadframe. This final step, alsoreferred to as singulation or trim and dejunk, results in individuallypackaged IC or power devices ready for electrical test. The remainder ofthe leadframe, including tie bars, rails, etc., is then recycled torecover the copper for future use.

One major disadvantage of leaded package technology is that each packageneeds its own mold, commonly requiring an initial investment of over$100,000 USD. Manufacturers must consider this initial cost whenperforming calculations regarding their expected financial return oninvestment of ROI, and the TTR, i.e. the time required for recoupingtheir investment. The unintended consequence of high initial investmentis that companies become more cautious about releasing new packages intothe market, new package technology and capability become commerciallyavailable at a slower pace, and consequentially innovation andadvancement slow to a snail's pace. These factors explain why powerpackages have progressed very little over the last five decades.

Another consideration in manufacturing is affect of UPH or units perhour throughput on unit cost. Unit cost comprises material and laborcosts plus the initial investment divided by the UPH. High initialinvestment and low UPH both adversely contribute to product cost. WhileUPH for molding machines is high, productivity is sacrificed every timethe factory switches packages. To change from one package to another, amold machine must be taken out of service and the mold cavity tool, themachined steel blocks that define where the plastic goes, must bemanually changed. The mold machine must be reheated, and recalibratedoften with some test runs to confirm that it is working well beforerunning any production material through it. Down time for changing themold tool can be an hour or longer, reducing the average throughput andincreasing production net cost per unit. As much as possible, factorymanagement will choose to avoid changing the mold tool during a workshift, delaying a specific customer's production for one or more shifts,or even for days to maximize factory throughput, even at the expense ofcustomer service.

An example of a leaded surface mount package leadframe, before and aftermolding, is shown in FIG. 3A. Photo 30A illustrates IC leadframe 33Aprior to molding including conductive leads 33A and die pad 33B. In theexample shown the lead frame comprises 22 leads on each of two sides ofthe plastic body thereby comprising a 44 lead, also known as a 44-pin,surface mount package. After molding, as shown in photo 30B, the diepad, semiconductor die and bond-wires are encapsulated by plastic,leaving only the exterior portion of conductive leads 33B exposed.During manufacturing, every die pad is covered by its own separatelymolded plastic, as defined by a mold cavity tool uniquely for thespecific package type. After singulation, i.e. separating the packagefrom the leadframe, the resulting package is shown in perspectivedrawings 33A and 33B. The number of conductive leads may varyconsiderably, with dual-sided packages having from two to seven dozenleads on each side. Common dual-side packages include 3, 4, 6, 8, 12,16, 18, 20, 24, 28, 32, 36, 40, 44 and 48 leads in total.

FIG. 3B illustrates several examples of small outline or “SO” typepackages including the ubiquitous SO-8, a small outline package with8-leads 33E shown in perspective view 31E from above and from underneathin view 32E. As shown, package 31F has 10-leads 33F, and package-31Gincludes 16-leads 33F. The package shown in topside view 31D includes20-leads 33D. The underside view 32D of the same package illustratesexposed die pad 34D used to improve thermal conduction. Guaranteeingcoplanarity between exposed die pad 34D and the bottom of leads 33D inmanufacturing however remains problematic. Therefore most SO typepackages such as the 36-lead package shown in topside view 31C andunderside view 32C do not include an exposed die pad and are notintended for power applications.

Low pin count packages such as those shown in FIG. 3C are commonly usedfor single transistors, dual transistors, or small analog integratedcircuits such as voltage regulators, provided that the component's powerdissipation is limited. Such packages may include the small outlinetransistor or SOT23 package 31K having three leads 33K, the thin smalloutline package or TSOP including a 5-lead version 33H shown in topsideand underside views 31H and 32H, 6-lead version 33L shown in topsideview 31L, and the improved area efficiency J-lead wide-body packageknown as the TSOP-JW shown in topside and underside views 31J and 32J.Leads 33J bend underneath the package to accommodate a larger packagebody and die area than conventional gull wing packages. While the namesuggests the package lead has a J shape, the process of mechanical leadbending actually produces an inverse gull wing, essentially the same asother gull wing packages except the leads are bent under the packagebody instead of outside.

Higher pin count packages utilize the placement of gull wing shapedleads on all four sides of a package, and are therefore referred to asleaded quad flat packs or LQFP packages. As shown in FIG. 3D topside andunderside views 31M and 32M illustrate a 32-lead LQFP having 8 gull-wingleads 33M on each side of the package while topside and underside views31N and 32N illustrate a 48-lead LQFP having 16 gull-wing leads 33N perside. Topside and underside views 310 and 320 illustrate a LQFP withgull wing leads 330 and exposed die pad 340. As in the previous SOpackage description, maintaining good coplanarity between the bottom ofexposed die pad 340 and leads 330 is problematic since the alignment isentirely mechanical and subject to unavoidable manufacturingvariability. This variability is especially severe in low profilepackages so LQFP packages with exposed die pads typically have heightsof 1 mm or greater.

Another class of packages comprising bent and stamped metal leadframesare those used in transistor outline or “TO” type power packages such asthe aforementioned DPAK and D2PAK as shown in top perspective views 31Pand 35P and top view 31Q in FIG. 3E. The conductive leads 33P and 33Qare bent into place during manufacturing ideally to be coplanar with thebottom of heat tab 36Q. Leads 33Q as shown, vary in width being slightlywider in the middle of the lead. This extra metal is left over from tiebars used to hold the leadframe together during manufacturing. Theleadframe construction of view 30R shown prior to trimming andsingulation illustrates the location of tie bar 37R connected to leads33R as well as die pad 34R and heat tab 36R. While the top view appearscoplanar, the actual leadframe is mechanically stamped into amulti-planar construction shown in perspective view 30S, where die pad34S and heat tab 36S are stamped and compressed to a height below thatof leads 33S and tie bar 37S.

In contrast to the traditional DPAK and D2PAK of the prior illustration,FIG. 3F illustrates various alternative packages comprising acombination of DPAK-like heat sink design with an eight lead packagesimilar in outline to the SOP8. In top view 38A, the power device sitsatop a die pad connected to four leads 40A and where bond wires 39Aconnect the die's top metallization to three leads used to carry highcurrent and to another lead for the transistor's gate or input. In topview 38B, the power device sits atop a die pad connected to four leads40B and a bond wire connects to the gate input lead but thepower-carrying bond wires have been replaced with copper clips 39B. Topviews 38C and 38E illustrate alternate designs for clip leads 39C and39E. Top view 38D illustrates the use of a large number of gold orcopper wires 39D to achieve a low package resistance while eliminatingthe need for large diameter bond wires or clips. Finally perspectiveview 38F illustrates an alternate clip lead design 39F where even thegate lead is connected by a copper clip. As clearly illustrated even inclip lead designs, the copper clip comprises leads that are mechanicallybent in portion 41F so that the bottom of the clip lead 40F is designedto be coplanar with the back of heat tab 42F.

In manufacturing however, maintaining coplanarity remains problematicespecially in low-profile package designs. The issue of coplanarity isrevealed in the SEM cross sections shown in FIG. 3G, where the back ofthe exposed die pad and heat tab 42F should be coplanar with flatportion 40F of lead 41F after bending. Too much bending will result inthe lead 41F and its flat portion 40F extending below die pad and heattab 42F, while too little bending has the opposite effect, causing belowdie pad and heat tab 42F to extend below lead 41F and its flat portion40F. As shown solder 44F wets onto the side of lead 41F but because ofthe thickness of lead 40F and flat portion 41F the solder is unable tocover the lead thoroughly. As such additional solder 43F must bemanually positioned onto a PCB before mounting the device in order toinsure solder 43F solders lead 41F and exposed die pad and heat tab 42Fto board reliably. Examples of a SOP type small power packages are shownin the photographs of FIG. 3H illustrating the underside view 45G of apackage with four leads 40G not connected to the die pad and one exposeddie pad 42G with a connected heat tab. Underside view 45H illustrates adesign where exposed die pad 42H does not connect to a heat tab butinstead connects to four additional leads other than leads 40H notconnected to die pad 42H.

Lastly in FIG. 3J, and number of leaded power packages such as TO220andvariants thereof are shown. While these packages are not surface mountdevices in the sense that the package leads do not solder flat onto aPCB, the heat tab may be attached or surface mounted onto a heat sinkfor additional cooling. Top view 45J and underside view 46J illustrateone such package with two through-hole leads 40J. A similar package isshown in top perspective view 45N and underside view 46N. Top-view 45Killustrates another package with two long through-hole leads 40K andheat tab 42K. Top view 45L and underside view 46L illustrate one suchpackage with three long through-hole leads 40L and heat tab 42L.Perspective view 45O illustrates a long lead package with seven leads40O and heat tab 42O. Top perspective views 46P and 45O reveal a packagewith heat tab 42P and complex lead bending resulting in leads 40P bentinto two distinct rows. Mounting of packages with two rows of bent leads40M is shown in side perspective view of power package 45M mounted on aPCB.

Leadless Packages Another class of surface mount semiconductor packageis the “leadless” or “no lead” package. Unlike leaded packages where theconductor connecting the semiconductor die to the outside worldprotrudes out the sides of the package's protective plastic body, in aleadless package, the conductors connected to the device or IC areavailable for connection to a PCB only on the underneath side of thepackage and not through leads protruding from the package.

Because no leads protrude from the package, leadless packages haveseveral unique properties, some advantageous and some restrictive. Beingleadless, the areal efficiency of leadless packages is significantlyimproved compared to leaded packages. Package area efficiency, themaximum die size divided by the external footprint, i.e. the lateralextent of the leads or plastic whichever is larger, is poor for leadedpackages because a lot of space is wasted by the need to bend the leaddown to the PCB surface. Package area efficiencies of 20% to 30% orworse are not uncommon for small packages like SOT and TSOP packageswhere significant portions of the package's area and volume are “wasted”by plastic and metal available for the semiconductor die. In contrast,leadless package can have area efficiencies in the 70% to 80% range. Andbecause no metal extends from the sides of the leadless package, thereis less risk of electrical shorts to neighboring components. As a resultother components on a PCB can be put closer to a leadless package thanto a leadless one, i.e. leadless packages don't require as large ofkeep-out zone on the PCB. The benefit of a smaller “keep-out” is ahigher PCB areal efficiency, meaning it is possible to pack moresemiconductor die area in the same PCB space. So leadless packages offerboth better package areal efficiency and PCB areal efficiency thanleaded packages.

Another benefit of leadless packages is they are intrinsically coplanar.As an artifact of its manufacturing process, the bottom of everyelectrical connection appearing on the underside of a leadless packageare, by definition, in the same geometric plane as all the othersbecause they constitute a common piece of copper. No lead bending isinvolved in forming the pins so no mechanical variability is present informing the package's exposed conductors, also known as outer leads or“lands”.

Moreover, since the die pad is formed from the same uniformly thickcommon copper sheet as the exposed conductors comprising the package'selectrical connections or conductive lands, the bottom of the die pad isintrinsically coplanar with all the package's connections. Consequently,the die pad of a leadless package is naturally exposed on the package'sunderside, i.e. not isolated from the PCB, as an unavoidable artifact ofits manufacturing process. If an isolated or unexposed die pad isdesired, extra-steps must be incurred in the leadless packagefabrication sequence to insure plastic fully encapsulates the die padduring molding.

The upper drawing in FIG. 4 illustrates the cross section of a leadframe50 showing multiple products being manufactured concurrently. As shown,semiconductor die 54A is attached to exposed die pad 51A using eitherconductive or insulating epoxy. Bond wire 55A electrically connectssemiconductor die 54A to conductive land 51B, and bond wire 55Belectrically connects semiconductor die 54A to conductive land 51C. Theentire device including the leadframe, die, and bond wires isencapsulated in molded plastic 56. In an adjacent section of leadframe50, semiconductor die 54B is attached to exposed die pad 51D andelectrically connected to landing pad 51E by bond wire 55C and otherconnections (shown only in part). Separate products are defined by sawlines 59, so although conductive lands 51B and 51E, and similarlyconductive lands 51C and 51F actually comprise common pieces of copper,during sawing they are separated into different products.

During singulation, sawing, or optionally mechanical punching, cuts aremade through both molded plastic 56 and the copper leadframe to separateone product from its neighbors and to cut away any connection to theleadframe rails or tie bars. The resulting singulated product is shownby example in the lower drawing of FIG. 4 for the product containingsemiconductor die 54A. Because sawing along line 51B cuts both copperand plastic, the lateral extent of conductive land 51B and moldedplastic 56 are coincident with vertical saw line 59, forming a verticalsidewall to the leadless package. Because of its manufacturing process,no lead can protrude laterally beyond the plastic giving the package itsdescription as “leadless”.

To mount a leadless package onto a printed circuit board, electricallyconnecting conductive lands 51C and 51B and exposed die pad 51A to PCBconductive traces 7, a layer of solder or solder paste 61 must beapplied before placing the package onto the PCB. This means solder orsolder paste 61 must be printed or screened onto the PCB in selectplaces as part of PCB manufacturing. After the product is positioned ontop of the solder paste, the PCB is run through a “reflow oven” or beltfurnace to heat the solder paste past its melting point and electricallyand mechanically connect the product's conductive lands 51C and 51B andexposed die pad 51A to the PCB conductive traces 7. Because, however,the solder paste must be screened onto the PCB in advance, and anexpensive temperature regulated reflow oven or belt furnace is required,manufacturing cost for reflow PCB manufacturing can be twice to fourtimes the cost of simple wave-soldering, where the PCB and componentsare simply dipped in solder. This higher PCB assembly cost representsone of the major disadvantages of leadless packaging.

The manufacturing process for leadless packages is illustrated in theflow chart shown in FIG. 5, where a copper sheet (step 60) is eitheretched or stamped (step 61) to define the leadframe's die pad,conductive lands, tie bars, and rails, then plated with a solderablemetal (step 62) such as tin, nickel, etc. to inhibit oxidation of thecopper. Once the lead frames are prepared, product manufacturing maycommence comprising die attach (step 63), wire bonding (step 64),molding (step 65), sawing or punching for singulation (step 66), anddeflash etching (step 67) to remove any plastic residue leftover fromsawing or punching.

Unlike leaded packages, where each individual part requires its ownpredefined mold cavity to isolate the plastic around a single product,in leadless package manufacturing entire matrices or arrays of productsare assembled and then molded into one common block of plastic. Thisprocess is illustrated pictorially in FIG. 6A where one common leadframe70A prior to molding comprises the die pads and conductive lands forhundreds of distinct and separate products 71A on a single leadframe.The leadframe after molding 72A however contains only a few large blocksof molded plastic 73A, each block containing dozens of products to beseparated by sawing or punching. As such different size products can bemanufactured simply by changing the leadframe with no change required inthe molding machine or mold cavity tools. This feature, the ability tomake different sized products represents an important benefit ofleadless package manufacturing and one compelling advantage explainingthe broad success and ubiquity of the package today.

A variety of four sided leadless packages made using the aforementionedprocess are illustrated in FIG. 6B. Using a nomenclature borrowed fromfour-sided leaded packages, i.e. the LQFP or the leaded quad flat pack,four-sided leadless packages are referred to as quad flat no-leadpackages or QFN packages. The term four-sided or quad means thatelectrical connections are present on all four edges of the package butare not necessarily limited to having the same number of conductivelandings on each edge. For example, the QFN shown in bottom view 75B hasa total of 20 conductive landings 76B comprising 6 conductive landingson two edges and four conductive landings on the other two edges. Italso has an exposed die pad 77B, which may electrically be connected toone of the conductive landings.

The top perspective view 74B clearly reveals no leads are evident on thepackage or protruding from its sides. Only small pieces of metal,saw-cut flush with the plastic package sidewall, reveal the location ofthe conductive landings. While constituting a visibly identifiablefeature, the exposed metal on the package vertical sidewall is notsufficient in area for soldering. Instead, electrical connection must bemade underneath the package, directly to conductive landings 76B.Similarly, underside view 75C illustrates a package with 48 conductivelanding pads 76C, sixteen on each edge as well as an exposed die pad77C. The top view 74C shows no protrusions identifying the presence ofconductive leads. Underside view 75D illustrates a underside view of aQFN type leadless package with an exposed die pad 77D and 40 conductivelandings 76D, ten on each edge and its corresponding topside view.Another QFN package design also with 40 conductive landings 76E is shownin underside view 75E except that die pad 77E is larger than that of diepad 77D in the previous design.

Four-sided QFN leadless packages are commercially available in fixed mmincrements, e.g. 2×2, 3×3, 4×4, 5×5, 6×6, etc. While the packagedimensions may be standardized, there is no corresponding standardizedsize for the exposed die pad. For example, underside view 74F in FIG. 6Cillustrates a package with 48 landing pads 76F, sixteen on each of foursides, but with an exposed die pad 77F comprising only a small fractionof the total package area and footprint. Variations in die pad designare especially evident in smaller QFN packages such as contrasted by thepackage with underside view 75L having a large die pad 77L with 16conductive landings versus the package of underside view 75J having arelatively large die pad 77J with 12 conductive landings.

As shown in FIG. 6D, leadless packages are also available in selectedrectangular versions, generally with low aspect ratios, e.g. 2×3, 3×5,etc. For example, a rectangular QFN shown in top perspective view 74Qand underside view 75Q comprises 38 conductive landings 76Q combining 12conductive landings positioned along the package's long edges with 7conductive landings located on the short edge. Exposed die pad 77Q maybe electrically connected to one or more of the conductive landings orbe electrically isolated, enabling the package to support 39 distinctelectrical connections.

In another variation in leadless package design, conductive landings arelocated on only two of the package's edges instead of all four. Suchpackages are referred to as DFN packages, where DFN is an acronym fordual-sided flat no-lead packages. Examples include the DFN package shownin underside view 75P comprising elongated die pad 77P and sixconductive landings 76P and package shown in underside view 75T alsocomprising 6 conductive landings 76T and an alternately shaped die pad77T. As in the prior examples, die pad 77T may be electrically shortedto one or more of the conductive landings or may be electricallyindependent. In the design shown in underside perspective view 75R, arectangular DFN comprises exposed die pad 77R with 7 conductive landingson each long edge of the package.

In the extreme, the DFN design can be adapted for as little as twoconductive landings 76K as shown in the package with underside view 75Kas shown in FIG. 6E. Exposed die pad 77K functions as a third electrodemaking the package shown in topside perspective view 74K suitable forsingle transistors. Another leadless package for transistors is shown inthe underside view 75S comprising two conductive landings 76S and smalldie pad 77S.

Leadless package manufacturing for QFN and DFN packages can also supportdual die designs using two separated die pads as illustrated by therectangular package shown in FIG. 6F. For example, in topsideperspective view 74G and corresponding underside view 75G, a QFN packagecomprises two distinct exposed die pads 77G, six evenly spacedconductive landings 76G on the package's two short edges and sevenunevenly spaced conductive landings on both of its long edges. Despiteits unique dual die pad design, topside perspective view 74G appearsidentical to a single pad package of the same dimensions. Another dualdie pad package shown in above perspective view 74H and in undersideview 75H has two distinct exposed die pads 77H with six conductivelandings 76H, three on each of two edges. A longer aspect ratio designis illustrated by the package with underside view 75U with 8 conductivelandings 76U and two separate die pads 77U. In PCB assembly care must betaken to prevent shorts between the two die pads by insuring sufficientspacing.

As illustrated in FIG. 6G, leadless packages can also be manufacturedwithout any exposed die pad. For example the DFN package with undersideview 75N comprises eight conductive landings 76N three each on opposingedges while the underside view 75O represents a package with tenconductive landings 76O. As stated previously, in the leadlessfabrication sequence described, extra processing steps must be includedto eliminate the exposed die pad.

Lastly in FIG. 6H, a QFN with a curved edge is illustrated whereconductive landings 76M and the width of the base of the package shownin underside view 75M is larger in dimension than the top of the packageshown in topside perspective view 74M. Such a package cannot bemanufactured in the standard process described for QFN and DFNfabrications because sawing or punching unavoidably results in aperfectly vertical edge sidewall to the package with all the plastic andmetal cut flush by the saw cutline. Instead, such a package requires aseparate mold cavity tool for each unique package much like themanufacturing of leaded packages like the SOP, SOT, and DPAK. Thismethod of manufacturing, defining the plastic location by the moldingprocess rather than by sawing, eliminates one of the major advantages ofleadless package manufacturing—the elimination of custompackage-specific mold cavity tools.

Summary Leadless packages offer unique advantages in flexible packagemanufacturing, coplanarity, low-profile capability, and the eliminationof the need for expensive package-specific mold cavity tools. For all ofits advantages, one major disadvantage of the QFN/DFN leadless packageis its inability to be used in wave-solder PCB factories. Because nometal lead protrudes laterally from the package, wave-soldering cannotpenetrate beneath the package to solder the die pad and the conductivelandings onto the PCB conductors. Instead, the solder must be screenedusing a mask onto the PCB before component placement. Also, solder flowmust be performed in expensive reflow ovens or belt furnaces making theentire PCB assembly process 2 to 4 times more expensive than that ofsimple wave-solder factory based production. Moreover, visual inspectionof leadless packages soldered to a PCB using simple automated camerainspection is impossible because the solder cannot be confirmed from thetop view. Instead expensive X-ray inspection equipment is required,adding cost and safety risk into reflow PCB manufacturing.

In contrast, leaded packages such as the SOP and SOT offer a costadvantage in PCB assembly because they are wave-solder compatible andeasily assembled onto low cost PCBs manufactured in fully depreciatedPCB factories dating back to the 1950's. Nevertheless, despite itsbenefit in PCB manufacturing, the actual package manufacturing of leadedpackages suffers from many issues including poor lead coplanarity, poormanufacturing control in the lead bending process, risk of plasticcracking during lead bending, risk of delamination between the plasticand leads, and inability to be scaled into low profile package,especially for package heights below 1 mm.

Poor coplanarity also renders leaded packages difficult to heat sinkusing exposed die pads because the package's bent leads do notconsistently align with the bottom of the die pad or heat slug. Becauseof long lead dimensions required to perform clamping during leadbending, the length of the conductive leads results in poor package andPCB areal efficiencies and results in excessive lead inductance,adversely affecting switching performance especially in powerapplications. The mounting of power devices is especially problematicbecause special two-step soldering is required, first to solder theexposed die pad and heat tab to the PCB, and then to wave-solder theleads. Variability in the lead-bending process combined with naturalstochastic variations in the intervening solder thickness placed beneaththe die pad result in unpredictable misalignments between the bottom ofthe bent leads and the PCB conductor, leading to poor connections, coldsolder joints, intermittent contact, and degraded reliability.

Another disadvantage of leaded packages is their manufacturinginflexibility. Several manufacturing steps required in leaded packagemanufacturing demand the use of dedicated machinery and hardware,including a package-specific mold cavity tool, package-specificleadframe trim-and-bending machinery, package-specific dedicatedhandlers, package-specific dejunk and deflash hardware, and more. Whileequipment can generally be converted to accommodate different packages,the resulting factory downtime to convert a line from one package toanother results in lost productivity and a lower UPH, thereby increasingper unit manufacturing costs.

The following table summarizes these and other considerations whencomparing existing package technologies.

Package Leaded IC Leaded Power Leadless Class Package Package PackageExample LQFP, SOP, TO (DPAK, QFN, DFN Packages TSOP, SOT D2PAK) PkgPackage Package Flexible, Manufacturing Specific SpecificInterchangeable Height Thick Very Thick Low-Profile (>1 mm) (>2 mm)(<0.8 mm) Lead Coplanarity Difficult Difficult Superior PowerDissipation Poor Superior Good PCB Factory Wave-Solder 2-Pass Reflow PCBCost Low Moderate High Inspection Optical Camera Optical, Some RequiresX-ray X-ray

Clearly from the above, no existing package meets the combined needs ofthe market. Moreover, each class of surface-mount package used todayrequires completely different semiconductor package factories formanufacturing, forcing packaging companies to choose their markets withlittle chance to expand into new markets without incurring significantadditional capital costs.

What is needed is a single package design and manufacturing process thatis able to produce surface-mount packages flexibly for both wave-solderand reflow assembly, facilitate superior coplanarity among the die padand conductive leads, achieve low package height, provide good thermalpower dissipation, minimize package inductance, and eliminate the needfor package specific equipment such as mold cavity tools and leadingequipment.

SUMMARY OF THE INVENTION

The process of this invention utilizes a leadframe that is preferably,but not necessarily, fabricated in accordance with the methods describedin the above-referenced U.S. application Ser. No. 14/056,287. Theleadframe comprises a plurality of die pads and leads. Each of the diepads and its associated leads generally correspond to a finishedpackage, although some packages may include two or more die pads. Someof the leads and die pads are connected together, the leads to beincluded in adjacent packages may be connected together across “streets”where the packages will eventually be separated, and for additionalstability during fabrication tie bars and rails may be used to connectthe die pads and leads to each other.

The leads may be Z-shaped when viewed in a vertical cross section and,if so, they each comprise a vertical column segment, a cantileversegment and a foot. The cantilever segment projects horizontally inwardtowards the die pad at the top of the vertical column segment, and thefoot projects horizontally outward at the bottom of the vertical columnsegment. The vertical column segment typically forms right angles andsharp corners with the cantilever segment and with the foot. The bottomsurface of the foot is coplanar with a bottom surfaces of the feet ofother leads and with a bottom surface of the die pad, if exposed. Inother embodiments, the lead does not comprise a foot, and it is alsopossible that the lead does not comprise a cantilever segment. A leadmay be attached to a die pad. In some embodiments, a heat slug extendsfrom the die pad to improve thermal conduction, and the heat slug mayterminate in a foot.

The leadframe may be fabricated using a process that comprises forming afirst mask layer on a backside of a metal sheet and then partiallyetching the metal sheet through openings in the first mask layer inareas where the cantilever segments of the leads are to be located, andwhere gaps between the leads and the die pads and between the leadsthemselves, are to be located, and in the areas between adjacentpackages. If the die pads are to be isolated, there are also openings inthe first mask layer where the die pads are to be located. If the diepads are to be exposed, the mask layer covers where the die pads are tobe located, and those areas are not etched. The partial etch through theopenings in the first mask layer does not cut through the entire metalsheet, and a thinned layer of metal remains in the etched areas.

The process further comprises forming a second mask layer on a frontside of the metal sheet, the second mask layer having openings overlyingthe gaps between the die pads and the leads and between the leads, theareas where the feet of the leads, if any, are to be located, and theareas between adjacent packages.

The metal sheet is then etched through the openings in the second masklayer. This etch is continued until the metal is completely removed inthe areas where the gaps between the die pads and the leads and betweenthe leads are to be located and in the areas separating adjacentpackages, but the metal is only partially removed in the area where thefeet of the leads, if any, are to be located. The openings in first masklayer under the cantilever segments of the leads and the openings in thesecond mask layer overlying the feet of the leads, if any, arevertically offset from each other such that segments of the metal sheetbetween the cantilever segments and the feet remain unaffected by eitherof the etch processes. These un-etched segments will become the verticalcolumn segments of the leads. If the die pads are to be exposed, theareas in which are the die pads are to be formed remain un-etched.

Alternatively, a metal stamping process may be used in lieu of the etchprocesses described above. A first metal stamp is applied to the firstside of the metal sheet to compress and thin the metal sheet where thecantilever segments of the leads and the gaps between the die pads andthe leads and between the adjacent packages are to be located (andoptionally where the die pads are to be located). A second metal stampis applied to the second side of the metal sheet to sever the metalsheet where the gaps between the die pads and the leads and betweenadjacent packages are to be located and to compress and thin the metalpiece where the feet of the leads, if any, are to be located.

Whether an etching or stamping processes is used, the result istypically a leadframe with multiple die pads, each die pad beingassociated with a plurality of leads. If the package is to have leadsonly on two opposite sides of the die pad (a “dual” package), the diepad is typically held in place in the leadframe by means of at least onetie bar. The leads on the contiguous sides of adjacent packagestypically extend across a “street” where the packages will be separated,or “singulated,” and are typically connected together by rails. If thepackage is to have leads on four sides of the die pad (a “quad”package), the die pad is sometimes left connected to at least one of theassociated leads, that is, no gap is formed between the die pad and theat least one of the associated leads in the above-described etching orstamping processes. Whether by a tie bar, an attached lead, or both, thedie pad remains connected to the leadframe.

Semiconductor dice are then mounted on their respective die pads, andthe appropriate electrical connections are made between the dice and theleads, typically using wire bonding or flip-chip techniques. Thebacksides of the dice may or may not be electrically and/or thermallyconnected to the die pads.

In accordance with the invention, rather than using separate molds toform the plastic capsules for each package, a single mold is used toform a single plastic block over a plurality of die pads, and theirassociated leads, tie bars and rails in the leadframe. The packages arethen singulated using one or more laser beams.

In many embodiments, the plastic block is separated into plasticprotective capsules for each of the packages using a first laser beam,which is normally moved in a series of parallel adjacent scans in theareas between the packages. Typically, the scans are performed in twosets, orthogonally related to each other, to separate the plastic intoindividual capsules.

After the plastic block has been separated into capsules for each of thepackages, a second laser beam is used to remove the metal conductorsthat typically connect adjacent packages and any rails that may connectthe metal connectors together. Again, this is normally performed in aseries of parallel adjacent scans in the “streets” between the packages.

By varying the total, combined width of the laser scans of the firstlaser beam, a wide variety of different types of packages may befabricated. For example, if the laser scans of the first laser beanextend to the top surfaces of the cantilever segments of the leads, thesidewalls of the plastic capsules will be located there, and the leadswill protrude from the sidewalls of the plastic capsule. If the laserscans of the first laser bean extend to the top surfaces of the columnsegments of the leads, the sidewalls of the plastic capsules will belocated there, and the outer sidewalls of the column segments willremain exposed. If the laser scans of the first laser bean extend to thetop surfaces of the feet of the leads, the sidewalls of the plasticcapsules will be located there, and the feet will extend from thesidewalls of the plastic capsule but the outer sidewalls of the columnsegments of the leads will remain covered by the plastic capsule. If thescans of the first laser beam cover only the “street” to be formed bythe scans of the second laser beam, the sidewalls of the plasticcapsules will be coplanar with the ends of the leads, and a leadlesspackage will be formed.

Preferably, the wavelength and other characteristics of the first laserbeam will be such that the first laser beam does minimal damage to themetal conductors embedded in or underlying the plastic block.

According to another aspect of the invention, a solder layer is printedon the bottom surfaces of the die pad, if exposed, and/or the bottomsurfaces of the leads. After singulation, a package treated in this waycan be attached to a PCB by merely placing the package on top of the PCBand heating the package and PCB so as to melt the solder layer. Ifdesired, the package may also to subjected to a wave-solder process toattach leads on which a solder layer has not been formed to appropriatetraces or contacts on the PCT.

The techniques of this invention thus allow a wide variety of differenttypes and sizes of semiconductor packages to be fabricated without theneed for specialized equipment. This is attained by essentially varyingthe patterns of openings in the mask layers applied to the backside andfront side surfaces of a metal sheet and by varying the combined widthof the laser scans used to separate the plastic block into capsules foreach package. Where footed packages are used, the bottom surfaces of thefeet are assured of being coplanar, and the difficulties inherent in thebending of leads to form gull-wing packages are avoided.

As a result, a semiconductor package manufacturer can produce packagesdesigned to meet its customers' specific needs economically and withoutundue delays.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings listed below, components that are generally similar aregiven like reference numerals.

FIG. 1A is a cross-sectional view of a leaded IC surface mount package.

FIG. 1B is a cross-sectional view of a leaded surface mount powerpackage with heat slug.

FIG. 2 is a flow chart for leaded surface mount package fabrication.

FIG. 3A comprises a topside view of leaded surface mount leadframe andpackage before and after molding.

FIG. 3B comprises topside and underside perspective views of variousdual-sided leaded IC surface mount packages.

FIG. 3C comprises topside and underside perspective views of variousdual sided low-pin-count leaded IC surface mount packages.

FIG. 3D comprises topside and underside perspective views of variousfour-sided LQFP leaded surface mount packages.

FIG. 3E comprises topside views of leaded surface mounted power packagesand leadframes.

FIG. 3F comprises topside and perspective views of IC surface mountleadframes adapted for power applications.

FIG. 3G is a side view of a surface mounted IC leadframe adapted forpower applications.

FIG. 3H comprises topside and underside views of IC surface mountpackages adapted for power applications.

FIG. 3I comprises topside and perspective views various leaded powerpackages.

FIG. 4 is a cross sectional comparison of a leadless package before andafter singulation.

FIG. 5 is a flow chart for leadless surface mount package fabrication.

FIG. 6A comprises a topside view of leadless surface mount leadframe andpackage before and after molding.

FIG. 6B comprises various topside and underside views of QFN four sidedleadless surface mount packages.

FIG. 6C comprises various alternate topside and underside views of QFNfour sided leadless surface mount packages.

FIG. 6D comprises various alternate topside and underside views ofelongated leadless surface mount packages.

FIG. 6E comprises various alternate topside and underside views of lowpin count leadless surface mount packages.

FIG. 6F comprises various alternate topside and underside views ofleadless surface mount packages with multiple exposed die pads.

FIG. 6G comprises various alternate topside and underside views of DFNdual sided leadless surface mount packages.

FIG. 6H is a topside and underside view of a leadless surface mountpackage using a dedicated QFN mold cavity tool.

FIG. 7A is a cross sectional representation of universal surface mountpackage (USMP) leadframe regions during double etching fabrication.

FIG. 7B is one possible flow chart for USMP leadframe fabrication.

FIG. 8A is a cross sectional illustration of a leadframe manufacturedusing a viable USMP fabrication sequence.

FIG. 8B is a cross sectional illustration of a leadframe manufacturedusing a problematic USMP fabrication sequence.

FIG. 9A is a cross sectional illustration of various two and threeregion geometric leadframe elements resulting from the disclosed USMPleadframe fabrication sequence.

FIG. 9B is a cross sectional illustration of various three regiongeometric leadframe elements resulting from the disclosed USMP leadframefabrication sequence.

FIG. 9C is a cross sectional illustration of various USMP geometricleadframe elements including fully etched portions.

FIG. 9D is a cross sectional illustration of various USMP geometricleadframe elements including fully etched portions.

FIG. 10A is a plan view of a USMP IC leadframe before molding.

FIG. 10B is a plan view of a block molded leaded IC leadframe.

FIG. 10C is a cutaway view of a block molded leaded IC leadframe.

FIG. 10D is a plan view of a segmented block molded leaded IC leadframe.

FIG. 10E is a plan view of a USMP DPAK leadframe before molding.

FIG. 10F is a plan view of a block molded DPAK leadframe.

FIG. 10G is a cutaway view of a block molded DPAK leadframe.

FIG. 10H is a plan view of a segmented block molded DPAK leadframe.

FIG. 11A is a cross sectional illustration of USMP package streetfabrication steps for a footed package.

FIG. 11B is a cross sectional illustration of USMP package streetfabrication for a leadless package.

FIG. 11C is a cross sectional illustration of USMP package streetfabrication for an alternate footed package.

FIG. 12A is a cross sectional illustration of USMP laser singulation andfoot formation.

FIG. 12B is graph of the optical absorption spectra of various metals.

FIG. 12C is a schematic representation of a laser system for USMP streetfabrication.

FIG. 12D is a leadframe illustrating USMP horizontal street fabrication.

FIG. 12E is a leadframe illustrating USMP vertical street fabrication.

FIG. 12F is a schematic of USMP street fabrication laser scan patternsfor plastic and metal removal.

FIG. 12G is a plan view of a USMP fabricated footed package.

FIG. 12H is a schematic of alternate USMP street fabrication laser scanpatterns for eliminating tie bar artifacts.

FIG. 13 is a USMP flow chart for footed and leadless packagefabrication.

FIG. 14A is a cross sectional view of USMP footed package fabricationillustrating starting copper sheet.

FIG. 14B is a cross sectional view of USMP footed package fabricationillustrating leadframe backside etch masking.

FIG. 14C is a cross sectional view of USMP footed package fabricationillustrating leadframe front side etch masking.

FIG. 14D is a cross sectional view of USMP footed package fabricationillustrating leadframe after front side etching.

FIG. 14E is a cross sectional view of USMP footed package fabricationillustrating leadframe after die attach.

FIG. 14F is a cross sectional view of USMP footed package fabricationillustrating leadframe after wire bonding.

FIG. 14G is a cross sectional view of USMP footed package fabricationillustrating leadframe after molding.

FIG. 14H is a cross sectional view of USMP footed package fabricationillustrating leadframe after laser plastic removal.

FIG. 14I is a cross sectional view of USMP footed package fabricationillustrating leadframe after laser singulation and foot formation.

FIG. 14J is a cross sectional view illustrating how the footed packagecan be converted into a leadless package.

FIG. 15A is a cross sectional view of USMP packages contrasting footedand leadless package types.

FIG. 15B is a cross sectional view of USMP packages contrastingalternate types of footed and leadless packages.

FIG. 15C is a cross sectional view of USMP packages contrasting footedand leadless package types but with isolated die pads.

FIG. 15D is a cross sectional view contrasting different types of leadedUSMP power packages.

FIG. 15E is a cross sectional view of a leaded power package fabricatedusing the USMP process.

FIG. 15F is a cross sectional view of a leaded surface mount powerpackage fabricated using the USMP process as a gull wing packagereplacement.

FIG. 16 is a perspective view of lead construction of footed packagesfabricated using the USMP process.

FIG. 17A comprises multiple views of a footed USMP package.

FIG. 17B comprises multiple views of an alternate embodiment of a footedUSMP package.

FIG. 17C comprises multiple views of a leadless package fabricated withthe USMP process.

FIG. 17D comprises multiple views of an alternative embodiment of aleadless package fabricated with the USMP process.

FIG. 17E comprises multiple views of another alternative embodiment of aleadless package fabricated with the USMP process.

FIG. 18A comprises multiple views of a leaded package fabricated withthe USMP process.

FIG. 18B comprises multiple views of a leaded surface mount packagefabricated with the USMP process.

FIG. 18C comprises multiple views of a power package heat tab fabricatedwith the USMP process.

FIG. 19A comprises cross sectional views of exposed and isolated die padUSMP leadframes along a cutline through a die-pad-connected foot and anisolated foot.

FIG. 19B comprises cross sectional views of exposed and isolated die padUSMP leadframes along a symmetric cutline through die pads and tie bars.

FIG. 19C comprises cross sectional views of exposed and isolated die padUSMP leadframes along a symmetric cutline through die-pad-connectedfeet.

FIG. 19D comprises cross sectional views of exposed die pad USMPleadframes along a cutline through a heat tab and feet.

FIG. 19E comprises a cross sectional view of an exposed die pad USMPleadframes along a cutline through a heat tab and tie bar.

FIG. 19F comprises cross sectional views of exposed and isolated die padUSMP leadframes along a symmetric cutline through feet not connected tothe die pad.

FIG. 19G comprises cross sectional views of exposed and isolated die padUSMP leadframes along a symmetric cutline through die pads.

FIG. 19H comprises cross sectional views of exposed die pad USMPleadframes along a symmetric cutline through dual die pads with andwithout tie bars.

FIG. 19I comprises cross sectional views of isolated die pad USMPleadframes along a symmetric cutline through dual die pads with andwithout tie bars.

FIG. 19J comprises cross sectional views of mixed isolated and exposeddie pad USMP leadframes along a symmetric cutline through dual die padswith and without tie bars.

FIG. 19K comprises cross sectional views of isolated die pad USMPleadframes along a symmetric cutline through dual die pads and die-padconnected feet.

FIG. 19L comprises a cross sectional and bottom view a Z-shaped foot notconnected to a die pad.

FIG. 20A comprises various views of a 2-footed USMP with isolated andexposed die pads.

FIG. 20B comprises various views of an alternate embodiment of a2-footed USMP with isolated and exposed die pads.

FIG. 20C comprises various views of a 2-footed USMP with isolated andexposed die pads and a three-sided foot.

FIG. 20D comprises various views of an alternate embodiment of a2-footed USMP with isolated and exposed die pads and a three-sided foot.

FIG. 21A comprises various views of a 3-footed USMP with isolated andexposed die pads.

FIG. 21B comprises various views of a 3-footed USMP with isolated andexposed die pads and a three-sided foot.

FIG. 21C comprises various views of a 3-footed power USMP with heat tab.

FIG. 21D comprises various views of an alternate embodiment of a3-footed power USMP with heat tab.

FIG. 22A comprises various views of a 4-footed USMP with isolated andexposed die pads.

FIG. 22B comprises various views of a 6-footed USMP with isolated andexposed die pads.

FIG. 22C comprises underside views of 8, 12, and 18-footed USMPs withexposed die pads.

FIG. 22D comprises underside views of 8, 12, and 18-footed USMPs withisolated die pads.

FIG. 23A comprises underside views of 16-footed USMPs with single anddual exposed die pads.

FIG. 23B comprises underside views of alternate embodiments of 16-footedUSMPs with dual exposed die pads.

FIG. 23C comprises underside views of 16-footed USMPs with dual isolateddie pads.

FIG. 23D comprises underside views of 16-footed USMPs integratingisolated and exposed die pads.

FIG. 24A comprises underside views of 16-footed USMPs integrating dualexposed die pads with enhanced pad-to-pad spacing.

FIG. 24B comprises underside views of alternative embodiments of16-footed USMPs integrating dual exposed die pads with enhancedpad-to-pad spacing.

FIG. 24C comprises cross sectional views of 16-footed USMPs integratingdual exposed die pads with enhanced pad-to-pad spacing.

FIG. 24D comprises cross sectional views of alternative embodiments of16-footed USMPs integrating dual exposed die pads with enhancedpad-to-pad spacing.

FIG. 24E comprises cross sectional views of alternative embodiments of16-footed USMPs integrating dual exposed die pads with enhancedpad-to-pad spacing.

FIG. 24F comprises cross sectional views of alternative embodiments of16-footed USMPs integrating dual exposed die pads with enhancedpad-to-pad spacing.

FIG. 24G comprises cross sectional views of a 16-footed USMPsintegrating a single exposed die pads cantilever lead extensions

FIG. 24H comprises cross sectional views of a 16-footed USMPsintegrating an exposed die pad, an isolated die pad, and a cantileverlead extension

FIG. 24I comprises cross sectional views of an alternative embodimentsof 16-footed USMPs integrating an exposed die pad, an isolated die pad,and a cantilever lead extension

FIG. 24J comprises cross sectional views of other alternativeembodiments of 16-footed USMPs integrating an exposed die pad, anisolated die pad, and a cantilever lead extension

FIG. 25A comprises underside views of 16-footed USMPs integratingexposed die pads with isolated interconnections.

FIG. 25B comprises underside views of alternative embodiments of16-footed USMPs integrating dual exposed die pads with isolatedinterconnections.

FIG. 26A comprises a perspective view of a 16-footed quad USMP.

FIG. 26B comprises an underside view of a 16-footed quad USMP with anexposed die pad.

FIG. 26C comprises an underside view of a 16-footed quad USMP with anisolated die pad.

FIG. 27A comprises underside views of 4 and 6-footed quad USMPs withexposed die pads.

FIG. 27B comprises underside views of 8 and 10-footed quad USMPs withexposed and isolated die pads.

FIG. 27C comprises underside views of 8-footed quad USMPs with exposedand isolated die pads and die-pad attached feet.

FIG. 27D comprises underside views of 8 and 10-footed rectangular-shapedquad USMPs with exposed and isolated die pads.

FIG. 28A comprises underside views of 12-footed quad USMPs with exposedand isolated die pads.

FIG. 28B comprises underside views of 16-footed rectangular-shaped quadUSMPs with exposed and isolated die pads.

FIG. 29A comprises an underside view of a 20-footed rectangular-shapedquad USMP with an exposed die pad.

FIG. 29B comprises an underside view of a 20-footed rectangular-shapedquad USMP with an isolated die pad.

FIG. 30A comprises an underside view of a 48-footed quad USMP with anexposed die pad.

FIG. 30B comprises an underside view of a 48-footed quad USMP with anisolated die pad.

FIG. 30C comprises an underside view of an alternate embodiment of a48-footed quad USMP with an isolated die pad.

FIG. 31 comprises various views of a power USMP integrating a multi-footpackage with an extended heat tab.

FIG. 32A comprises various views of a USMP including intra-lead tiebars.

FIG. 32B comprises an underside view of a USMP leadframe with intra-leadtie bars.

FIG. 32C illustrates the primary laser paths for defining package leadsand performing singulation of a quad USMP.

FIG. 32D comprises an underside view of a USMP package with intra-leadtie bars after singulation.

FIG. 32E illustrates an underside view of a quad USMP illustrating lasertie bar removal.

FIG. 33A comprises an underside view of dual isolated pad USMPsutilizing intra-lead tie bars.

FIG. 33B comprises an underside view of alternative embodiments of dualisolated pad USMPs utilizing intra-lead tie bars and isolatedinterconnects.

FIG. 34A comprises an underside view of a wave-solderable heat tab powerUSMP including a thermal comb.

FIG. 34B comprises an underside view of a wave-solderable heat tab powerUSMP leadframe including a thermal comb.

FIG. 34C illustrates the primary laser paths for defining package leadsand performing singulation of a power USMP with a heat tab.

FIG. 35A comprises an underside view of an alternative embodiment of awave-solderable heat tab power USMP with a thermal comb.

FIG. 35B comprises an underside view of an alternative embodiment of awave-solderable heat tab power USMP leadframe.

FIG. 35C comprises an underside view of a USMP power packageillustrating laser formation of a thermal comb.

FIG. 36A comprises an underside view of a wave-solderable heat tab powerUSMP with a bolt-hole.

FIG. 36B illustrates laser paths for forming a bolt hole in awave-solderable heat tab power USMP.

FIG. 37 illustrates a block diagram of various manufacturing flows forUSMP leadframe plating.

FIG. 38 illustrates a cross sectional view of a USMP pre-plated powerpackage leadframe.

FIG. 39 illustrates a cross sectional view of a USMP formed usingplating after molding.

FIG. 40 illustrates sequential cross sectional views of USMP fabricationcomprising selective leadframe plating.

FIG. 41A illustrates sequential cross sectional views of PCB assembly ofa USMP utilizing PCB solder printing.

FIG. 41B illustrates cross sections depicting potential manufacturingissues involving die tilt during USMP assembly.

FIG. 42A illustrates a block diagram of various manufacturing flows forUSMP fabrication including solder printing.

FIG. 42B illustrates USMP cross sections of power and exposed die pad ICpackages utilizing USMP pre-printed solder.

FIG. 43A illustrates a cross sectional representation of PCB USMPassembly steps utilizing USMP pre-printed solder.

FIG. 43B illustrates a cross sectional representation of PCB assemblyprior to wave-soldering, including both USMP power packages and USMP ICpackages.

FIG. 43C illustrates a cross sectional representation of PCB assemblyafter wave-soldering, including both USMP power packages and USMP ICpackages.

FIG. 44A illustrates USMP power packages with uniform and patternedpre-printed solder.

FIG. 44B illustrates USMP integrated circuit quad packages, both withuniform and patterned USMP pre-printed solder.

FIG. 44C illustrates test probe placement using pre-printed solder ofUSMP fabricated packages.

FIG. 45 illustrates a cross section of an isolated die pad withcustomized conformal heater blocks required in USMP manufacturing.

FIG. 46 illustrates cross sections of two variants of isolated die padUSMPs utilizing a thermally conductive electrically insulating pre-moldcompound.

FIG. 47 illustrates the fabrication flow chart of an isolated die padUSMP with a thermally conductive electrically insulating pre-moldcompound.

FIG. 48 illustrates an alternative embodiment of isolated die pad USMPfabrication utilizing thermally conductive electrically insulatingpre-mold compound.

FIG. 49A illustrates an overhead view of a saw type QFN3×3-12L leadframeand its corresponding footed USMP equivalent.

FIG. 49B illustrates an overhead view of a saw type QFN4×4-16L leadframeand its corresponding footed USMP equivalent.

FIG. 49C illustrates an overhead view of a punch type QFN4×4-24Lleadframe and its corresponding footed USMP equivalent.

FIG. 49D illustrates a table comparing saw type and punch 4×4 QFNleadless packages with the 4×4 QFF footed package

FIG. 49E illustrates an overhead view of a saw type TDFN5×6-8L leadframeand its corresponding footed USMP equivalent.

FIG. 50A illustrates an overhead view of a conventional TO-252 (DPAK)leadframe and its corresponding footed USMP equivalent.

FIG. 50B illustrates perspective and underside views of an alternativeembodiment of a footed DPAK.

FIG. 50C illustrates perspective and underside views comparingconventional and footed DPAK packages.

FIG. 50D illustrates perspective views and one underside view ofconventional and footed DPAK packages.

FIG. 50E illustrates a table comparing a conventional leaded DPAK to twofooted DPAK packages.

FIG. 51A illustrates an overhead view of a conventional SOT23 leadframeand its corresponding footed USMP equivalent.

FIG. 51B illustrates a table comparing conventional and footed SOT23packages.

FIG. 52A illustrates an overhead view of a conventional TSSOP-8Lleadframe and its corresponding footed USMP equivalent.

FIG. 52B illustrates an overhead view of an alternative embodiment of afooted TSSOP-8L leadframe and package.

FIG. 52C illustrates a table comparing conventional and footed TSSOP-8Lpackages.

FIG. 53A illustrates an overhead view of a conventional SOP-8L leadframeand its corresponding footed USMP equivalent.

FIG. 53B illustrates an overhead view of an alternative embodiment of afooted SOP-8L leadframe and package.

FIG. 53C illustrates a table comparing conventional and footed SOP-8Lpackages.

FIG. 54A illustrates an overhead view of a conventional LQFP7×7-32Lleadframe and its corresponding footed USMP equivalent.

FIG. 54B illustrates an overhead view of an alternative embodiments ofconventional and footed LQFP7×7-32L leadframes and packages.

FIG. 54C illustrates a table comparing conventional and footedLQFP7×7-32L leadframes and packages.

DESCRIPTION OF THE INVENTION

The above-referenced application Ser. No. 14/056,287 and ProvisionalApplications Nos. 61/775,540 and 61/775,544 relate to inventive methodsto make low profile wave-solder compatible semiconductor packages forintegrated circuits. These patent applications disclose methods tomanufacture low-profile footed packages in the same semiconductor ICpackaging facilities presently used to fabricate gull wing leadedpackages such as the SOP8 or SOT23. The patent applications alsodisclose methods to manufacture low-profile footed packages infacilities today used to manufacture leadless packages such as the QFNand DFN.

The above-referenced application Ser. No. 14/703,359 relates toinventive methods to make low profile wave-solder compatible powersemiconductor packages for discrete power devices such as the DPAK andD2PAK and other custom leaded packages adapted for power integratedcircuits using the same factories used today to manufacture thick, i.e.high profile, packages with thick mechanically bent leads.

From these patent applications, low-profile wave-solder compatible“footed” packages can be manufactured in present day factories withminimal or investment, pursuant to the following limitations:

-   -   Leaded IC package factories producing gull wing packages such as        the SOP8 and the SOT23 can be adapted to produce low profile        footed versions of the same packages, but cannot be used to        produce leadless packages or power packages without incurring        significant expense for new equipment and tooling.    -   Leadless IC package factories producing leadless packages such        as the DFN and QFN can be adapted to produce low profile        “footed” versions of the same packages compatible with        wave-soldering to replace leaded IC packages of the same        footprint (leadless packages are not), but cannot be used to        produce power packages without incurring significant expense for        new equipment and tooling.    -   Power package factories producing discrete power packages such        as the DPAK and D2PAK and power IC packages such as a power SOP8        can be adapted to produce low profile “footed” versions of the        same packages but cannot be used to produce leaded or leadless        IC packages without incurring significant expense for new        equipment and tooling.

The above bullet points highlight the fact that leaded package factoriesare fundamentally incapable of fabricating a diverse range of packagesbecause each package uses machine tools specific to a particularpackage. Package-specific equipment and tooling include:

-   -   Stamping, punching, and trimming machines used in leadframe        manufacturing    -   The mold cavity tool (and possibly the transfer mold machine        itself)    -   Trim and form tools for lead bending, singulation, cutting, and        dejunking, i.e. eliminating tie bars, rails, etc. after        fabrication is complete    -   Handling tools specific to each leadframe    -   Pick and place machines to pick up and pack the singulated        packages

All the above listed machines are specific to a particular package andgenerally incapable of being used to manufacture other package types.This inflexibility forces each package vendor to choose specificpackages to serve a particular segment of the market and that ifopportunity or demand arises for a different package it is unlikely, ifnot impossible, for them to adapt their factory to accommodate the newpackage.

Even in the unlikely event that a specific production line can beadapted to support another somewhat similar package, for exampleconverting a SOT23 line to a SOT223 line, the process is complex. Toconvert one package to another all the mold cavity tools must beswapped, the handlers must be changed, the trim and form machine must beconverted, and even the mold machine temperature must be recalibrated.The effect of all these modifications is a loss of productivity duringthe equipment conversion process, lowering overall throughput, i.e. thefactory's UPH or units per hour is reduced by the downtime. In economicterms, lower UPH means the cost per unit is higher, and the packagecompany's profitability and competitiveness is adversely impacted.

So although the aforementioned patent applications disclose methods toupgrade leaded packages to low-profile footed packages offering absolutecoplanarity for improved PCB manufacturing, and likewise provide a meansto produce wave-solderable footed packages in a factory previouslyincapable of producing anything but leadless packages, the disclosuresdo not facilitate a means to produce a plethora of packages in the samefactory and with minimal or no cost in converting factory machinery andtooling.

The method disclosed herein overcomes this package-specificmanufacturing inflexibility by combining the following features:

-   -   Dual-sided etched leadframe    -   Shared “block” mold for multiple packages and leadframes    -   Laser plastic and lead definition

Together these elements enable a single factory to manufacture avirtually unlimited combination of leaded, leadless, and power packages.Because of its ability to produce any number of different package typesincluding

-   -   Footed IC surface mount packages    -   Leadless IC surface mount packages    -   Footed power surface mount packages    -   Leaded IC packages    -   Leaded power packages        As such, the package disclosed herein is referred to as a        “universal surface mount package” or USMP.

Dual-Sided Etched Leadframe A package of this invention may befabricated from a leadframe with dual-side etching. Cross-sectional view80 in FIG. 7A illustrates a copper sheet 90, having a thickness of 200μm or 500 μm, used to form the USMP leadframe. Through etching, oralternatively through stamping, the copper sheet is modified into fourgeometric pieces, or segments.

Copper sheet 90 is subdivided into four segments A, B, C and D. Incross-sectional view 81 of FIG. 7A, a mask 83 protects segments A and Bbut exposes segments D and C to a backside etch, typically a liquid acidsolution for etching copper. After etching, copper sheet 90 is reducedin thickness to produce cantilever section 92 while section 91 retainsits full thickness. Alternatively, if the topside of copper sheet 90 isalso exposed to a copper-etch, the entire sheet 90, including section91, is reduced in thickness but cantilever section 92 is reducedproportionately.

In cross-sectional view 82 in FIG. 7A, a mask 84 protects segments A andC but exposes sections B and D to a frontside etch. During etching,segment B in section 91 is thinned to form a foot 100B while segment Dis completely cleared of all copper. If the etching occurs on only thefrontside, section 100A in segment A and cantilever 100C in segment Cremain unaffected. If however the etching occurs in an acid bath and thebackside of the copper leadframe 90 is unprotected, all sections arethinned proportionally.

The result of the fabrication sequence is four distinct segments.Segment A comprises the full thickness of the copper sheet, i.e. 100%.Segment C comprises etched copper cantilever 100C having a thickness ata fraction of the total thickness of copper sheet 90, e.g. 30%, having atop surface coplanar with the top of segment A. Segment B comprisesetched copper having a thickness at a fraction of the total thickness ofcopper sheet 90, e.g. 30%, having a bottom surface coplanar with thebottom of segment A. Segment D comprises opening 101D completely clearof metal.

The process flow for leadframe fabrication is shown in FIG. 7B, startingwith copper sheet 90 (step 95) followed by mask and backside etch (step96A), mask and frontside etch (step 96B), and finally the solder platingof the leadframe (step 97), where the leadframe is plated with tin,silver, nickel, palladium, or other solderable metals.

FIG. 8A illustrates the design parameters for etching copper sheet 90,shown in cross-sectional view 85. In order to preserve copper incantilever section C and foot section B while clearing all the metal insection D, the sum of the frontside etch and backside etch must exceed100%, preferably with a 10% overetch. For example, in cross-sectionalview 86A the front-side-etch removes 70% of the copper to form foot 100Bwhile backside etch removes 70% of the copper to form cantilever 100C.This embodiment of the invention produces equally thick cantilever andfeet sections.

Alternatively the front-side-etch removes more than the backside. Asshown in cross section 86B, the front-side-etch removes 70% of thecopper to form foot 100B while backside etch removes 40% of the copperto form cantilever 100C. This version produces a thick cantilever 100Cand a thin foot 100B. In another embodiment the backside etch removesmore than the front-side. As shown in cross section 86C, thefront-side-etch removes 40% of the copper to form foot 100B whilebackside etch removes 70% of the copper to form cantilever 100C. Thisversion produces a thin cantilever 100C and a thick foot 100B.

To insure the copper clears in sections where it should be removed thesum of the front and back etches must exceed 100% of the copperthickness. If the two etches are similar in time but do not exceed 100%of the starting copper thickness, unintended metal bridge 89 results asshown in cross-sectional view 87A of FIG. 8B. If the top etch is ofshort duration and the backside etch is of a long duration but togetherthe etches do not exceed 100% of the starting copper thickness,unintended metal bridge 89 results, as shown in cross-sectional view87B. If the top etch is of a long duration and the backside etch is of ashort duration but together the etches do not exceed 100% of thestarting copper thickness, unintended metal bridge 89 results, as shownin cross-sectional view 87C.

The process of leadframe manufacture in accordance with this inventionenables a variety of useful geometries to be fabricated shown in FIG.9A, including a column 100A comprising segment A; a foot 100B comprisingsegment B; a cantilever 100C comprising segment C; a half-T-shape 100Ecomprising the combination of segments A and C; an L-shape 100Fcomprising the combination of segments A and B; and also a Z-shape 100Gcomprising the combination of segments C, A, and B. Other usefulgeometries shown in FIG. 9B include an inverse T-shape 1004 comprisingthe combination of segments B, A, and B; a T-shape 100J comprising thecombination of segments C, A, and C, a U-shape 100L comprising thecombination of segments A, B, and A; and also an inverse U-shape 100Kcomprising the combination of segments A, C, and A.

Other useful geometric shapes fabricated by the disclosed process andshown in FIG. 9C combining copper elements and intervening gaps includegeometry 101M comprising columns A and intervening gap; geometry 101Ncomprising cantilevers C and intervening gap; geometry 101P comprisingfeet B and intervening gap; and also geometry 101Q comprising column A,foot B, and intervening gap. Similarly in FIG. 9D, geometry 101Rcomprises column A, cantilever C, and intervening gap; while geometry101S comprises foot B, cantilever C, and intervening gap. These variousgeometric elements are used to construct the leadframe and packagefeatures as disclosed herein.

Block Molding for Leaded & Leadless Packaging Another important elementof the USMP is the elimination of the need for package-specific moldcavity tools. Instead of localizing the plastic molding around eachspecific product, in the USMP process plastic is used to encapsulate allthe products in a common leadframe or divided portions thereof, i.e.“block” molding. By encapsulating large blocks of a leadframeconcurrently, the need for package-specific mold tools is eliminated. Asa result, many products may be manufactured on a single leadframeconcurrently from a common mold cavity tool, one shared with otherpackage types and leadframes.

For example, FIG. 10A illustrates an IC leadframe 105 designed for USMPfabrication comprising IC dice and individual leadframe patterns 106,leadframe rails 108, and leadframe cross rails 107. FIG. 10B illustratesUSMP leadframe 105 encapsulated by a single plastic block mold 109. FIG.10C illustrates USMP leadframe 105 and block mold 109 in cutaway viewrevealing multiple arrays of IC dice and individual leadframe patterns106 contained within. FIG. 10D illustrates USMP leadframe 105 covered bythree distinct blocks of plastic 110A, 110B and 110C collectivelycomprising a USMP segmented block mold. Depending on the laser plasticremoval and singulation process, the same leadframe can be used tofabricate either footed or leadless IC packages.

Using the USMP process and methods, the same leadframe used for ICs canbe adjusted to fabricate power packages as well. For example, FIG. 10Eillustrates an USMP power discrete leadframe 111 comprising powersemiconductor dice and individual leadframe patterns 112, leadframerails 108, and leadframe cross rails 107. FIG. 10F illustrates USMPleadframe 111 encapsulated by a single plastic block mold 109. Thedrawing of FIG. 10G illustrates USMP leadframe 111 and block mold 109 incutaway view revealing multiple arrays of power semiconductor dice andindividual leadframe patterns 112 contained within. FIG. 10H illustratesUSMP leadframe 111 covered by three distinct blocks of plastic 110A,110B and 110C collectively comprising a USMP segmented block mold formanufacturing power packages.

While block molding is used in leadless QFN manufacturing, except forthe USMP process disclosed herein, block molding is fundamentallyincompatible with leaded IC packages and power packages.

Laser Plastic and Lead Definition, Singulation One adverse consequenceof block molding in prior art package technology is that there is nomeans to produce a leaded package, i.e. the process of singulation on ablock mold invariably results in a leadless package, one where no leadsprotrude laterally past the plastic's edge. In other words, in presentday packaging, conventional methods used to rapidly remove plastic fromthe street naturally and unavoidably cuts the metal leads as well andvice versa. For example, during punch singulation, the sharp edges of amechanical die punch cuts entirely through both the plastic and thecopper leads, severing each package from its neighbors and leaving thevertical sidewalls of metal and plastic flush with one another.Similarly during saw singulation, the saw blade cuts completely throughboth the plastic as well as through the copper leads, severing eachpackage from its neighbors and leaving the vertical sidewalls of metaland plastic flush with one another. Practically speaking there is no wayto employ mechanical means to remove plastic without cutting the metal.

While conceivably, wet chemical means to remove plastic without etchingthe metal leads may be possible, the process of wet etching plastic isslow, imprecise, and expensive. The corrosive chemicals needed toperform the plastic etching also can damage, oxidize, or corrode themetal leads, affecting package reliability and lead solderability. Ionicchemical byproducts of the etching process can seep into the package,affecting the electrical stability of the package device or integratedcircuit. As an alternative, plasma etching, i.e. dry etching, of afinished package product can cause ionic charges to accumulate in thepackage and on the semiconductor dice, affecting device operation andelectrical characteristics. Moreover, chemical etching, whether wet ordry, requires added costs involving masking to define where the plasticis to be etched and where it is to be removed. Aside from its adverseexpense, masking a molded leadframe is not performed today and anentirely new set of tools and processes would have to be developedbefore such methods could be applied. As such, chemical and mechanicalmethods to etch a package street are not practiced, and singulation bysaw or punch represents a standard method.

In the disclosed USMP process flow, however, unwanted plastic is removedfrom the street between die by a laser process wherein the energy of alaser is precisely controlled to facilitate plastic removal withoutdamaging or cutting the copper leadframe. After laser removal of theplastic, the copper leads may then be cut by punch, saw, or in apreferred embodiment, also removed by laser. If a laser is used for bothplastic removal and copper lead cutting, then the laser's positioningcan be adjusted to create either leadless, leaded, or power packages inthe same manufacturing line.

One example of the USMP process for plastic removal and lead cutting,i.e. “street fabrication”, is illustrated in FIG. 11A. The threecross-sectional views illustrate packages for two adjacent dice, i.e.package A and package B and the intervening street between themdelineated by dashed lines, during three successive fabrication steps.Cross-sectional view 120 illustrates the step just after molding whereplastic-127A and copper conductor 128A extend between package-A andpackage-B through the intervening street. Plastic also fills the visibleunderside portion 131A of package A and 131B of package B

The second drawing, cross-sectional view 121, illustrates the use of alaser beam 130A to remove the portion of plastic 127A from the street,i.e. between the dashed lines, and in addition to remove portions ofplastic 127A on both sides of the street, i.e. atop copper conductor128A within package A and within package B, while the plasticencapsulating the die is retained and remains unaffected, i.e. a plasticcapsule 127B survives the process and continues encapsulating package-A,and a plastic capsule 127C survives, encapsulating package-B. To controlwhat plastic is removed and what plastic is left undisturbed, laser 130Ais optically scanned.

Optical scanning involves parametrically controlling the locations to belased, adjusting the power and pulse frequency of the laser, and varyingthe scan rate and number of repeated laser scans performed on a givenarea. The peak laser power needed for plastic removal varies from 5 W to20 W. For any given peak power setting, the average laser powerdelivered is controlled by pulsing the laser for a prescribed durationt_(on) at a fixed frequency f, resulting in duty factor D whereD=t_(on)·f_(pulse) and where the average powered delivered P_(ave) isgiven by P_(ave)=P·D=P·(t_(on)·f_(pulse)). For example a 20 W laserrunning at 20 kHz pulse rate and a 50% duty factor, has an on time of 25μsec for every 50 μsec pulse period, delivering an average power of 10W.

The laser's wavelength is adjusted to maximize its absorption by thematerial being removed. In the case of black colored plastic, virtuallyany infrared, visible light, or ultraviolet laser of sufficient power,e.g. in the 10 W to 20 W range, may be used to melt and evaporate therelatively low melting point of the plastic mold compound. When removingplastic sitting atop copper, however, it is beneficial to employ a laserwavelength that is absorbed by plastic but less so by the underlyingcopper leadframe metal, meaning at lower power levels, plastic canselectively be removed from the street without melting, burning, orscarring the underlying metal. Compared to black plastic, because of therelatively optical low absorption by copper and other “yellow” metals,laser wavelengths attractive for selective plastic removal made inaccordance with this invention include infrared gas lasers such as CO₂at 10.6 μm, or infrared solid-state or fiber lasers such as YAG at 1064nm.

To further avoid scarring of the underlying copper during laser plasticremoval, the required laser power may be reduced by rapidly andrepeatedly scanning the same area with the laser, whereby the totalenergy E_(scan) delivered to one specific “slice” of plastic to beremoved is equal to the average laser power P_(ave), describedpreviously, times the time required to scan across the slice t_(scan)times the number of times a given slice is scanned n_(scan), i.e.E_(scan)=n_(scan)·Pave·t_(scan). By employing the proper wavelength forthe material being removed, the number of scans n_(scan) can beminimized, typically from 2 to 5 scans. If however a laser having awavelength poorly matched to the material being removed is used, from 10to 30 scans may be required on each lased slice. A large number ofrepeated scans per slice, i.e. n_(scan)>5, is undesirable because itincreases processing time, lowering processing UPH, and increasing therisk of scarring the metal or burning of adjacent material in thepackage. For example, a UV or blue laser used to cut copper may requireonly 3 or 4 scans to remove a 200 μm copper leadframe, while an infraredlaser such as YAG or CO₂ may require 10 or more scans, resulting in burnmarks on the leadframe.

The scanning rate f_(scan)=1/t_(scan) should not be confused with theaforementioned laser pulse frequency f_(pulse) and the laser pulseduration t_(on), which occur at rates at least one or twoorders-of-magnitude faster than laser scanning. In micromachining, laserpulses are controlled electronically in the microsecond range, whileoptical scanning of lasers is performed using motors and movablemirrors. One-dimensional scanning, i.e. producing a cutline along astraight line, can be performed with a single mirror system whiletwo-dimensional scanning requires either using a single mirror rotatedon two axis, or by employing two mirrors—one for determining the x-axisposition control and the other for y-axis control. Mirror positioningcan be accomplished using precision adjustments with stepper motors orusing continuous drive rotating motors with the laser pulses occurringonly when the mirrors are directed toward the area to be lased.Importantly, because the laser and its operating settings are tuned forplastic removal, after plastic removal, copper conductor 128A continuesto hold all dice in place in the leadframe, undisturbed by laser 130A.

To estimate the process throughput, laser scan rates must be considered.Linear scan rates can reach 5,000 mm/s but for precision is slowed toaround 400 to 500 mm/s. For a 40 mm wide plastic block, this means asingle scan across the width of the block mold takes approximately 0.1s. By repeating 4 scans on one slice and breaking a street into 7slices, a total of approximately 30 scans can clear one street in thewidth-wise direction, i.e. requiring roughly 3 seconds to clear theplastic from each street. If a 40 mm wide block is roughly 40 mm long,then a 3×3 mm product results in a molded block comprising 15 horizontaland 15 vertical streets, or 30 streets in total. At 3 seconds perstreet, the block can be cleared of plastic in 90 seconds, i.e. in 1.5minutes. Assuming four blocks per leadframe, a total of 6 minutes arerequired for plastic removal. Smaller packages take longer because thereare more streets to clear for any given block's area. Conversely, largerpackages may be processed in shorter times in proportion to the lowerstreet density.

In the third step, shown in cross-sectional view 122 of FIG. 11A, adifferent laser process, laser 130B, is optically scanned to removecopper conductor 128A from the street, i.e. between the dashed lines.After lasing, copper lead 128B extends under plastic capsule 127B whilecopper lead 128C extends under plastic capsule 127C. Leads 128B and 128Care separated by the street. These and other copper conductorsprotruding from the plastic package body (but not shown in thisparticular cross section) collectively comprise the conductive feet ofthe disclosed footed package. The conductive leads have the same Z shapeas the aforementioned geometry 100G. As shown, plastic capsules 127B and127C cover the top portions of these leads but not the sidewall or feet,which are exposed. By removing metal 128A from the street, not only arethe conductive feet formed but also the packages are mechanicallyseparated from the leadframe and from one another. Laser 130B, thereforefabricates the package feet as well as performing product singulation.

To minimize the power and duration during metal cutting by improvingoptical absorption by yellow metals such as copper, laser 130B ideallycomprises a shorter wavelength than laser 130A. Short wavelength lasers,comprising solid-state or fiber lasers, include yellow-orange lasers at593.5 nm, green lasers at 532 nm, blue lasers at 473 nm, blue-violetlasers at 405 nm, or ultraviolet lasers at 375 nm, 355 nm, 320 nm, or266 nm. While excimer lasers, utilizing excited dimers of noble gasessuch as xenon, krypton, fluorine, and argon to realize ultravioletwavelengths are commonly employed in semiconductor manufacturing anddelicate surgeries, such precision and higher associated costs are notgenerally justified for package fabrication. Using the appropriatewavelength laser, throughput of metal removal and package singulationcan be even faster than plastic removal.

In an alternative embodiment, laser 130B is replaced by mechanicalsawing. In this alternative fabrication sequence, laser 130A is stillused to remove the plastic from the street and to uncover the feet, butmechanical sawing defines the length of the feet and performssingulation. This version of the process, while able to re-use existingmechanical sawing equipment, is less accurate than the laser process,and subjects the products to greater mechanical stress duringprocessing. The resulting package is inferior, having greatervariability in the length of the conductive feet, and greater risk ofplastic cracking. Moreover, care must be taken to control the saw rateand to replace the saw blade frequently, or the saw may damage the metaland bend the feet.

Although the disclosed two-laser process for street fabrication can beutilized to produce footed packages as shown in the prior drawing, FIG.11B illustrates the technology can also be applied to produce leadlesspackages. Starting with the same cross-sectional view 120 immediatelyafter molding, in cross-sectional view 123, laser 130A is used to removeplastic only from the street. After laser 130A processing, plasticcapsule 127B encapsulates die-A and plastic capsule 127C encapsulatesdie-B but conductive copper 128A is uncovered only in the street. As inthe previous example, plastic 127A is removed only in the street bycontrolling the laser positioning during scanning.

In cross-sectional view 124, a second laser process, laser 130Btypically having a higher power and energy rating than laser 130A, isused to cut and remove copper conductor 128A from the street. Becauseplastic removal by laser 130A and metal removal by laser 130B both havethe same edge as defined as the edge of the street, then the resultingplastic and metal form a flush vertical wall at the package edge. Asshown, conductive copper lead 128B is flush with plastic capsule 127Bdefining the vertical edge of die-A, identical in cross section to aconventional sawed leadless QFN or DFN package. Similarly, conductivecopper lead 128C is flush with plastic capsule 127C defining thevertical edge of die-B. Street fabrication and die singulation in theUSMP process using lasers is superior to sawing in conventional QFNfabrication because of improved accuracy, reduced stress on the packageplastic, reduced risk of plastic cracking, smoother package edges, andreduced risk of metal-to-plastic delamination.

Beyond its improved quality and manufacturability, the USMP process isable to fabricate both footed and leadless packages in the same factoryand manufacturing line with no retooling required. The USMP process isuniversal because it can make both wave-solder compatible leaded, i.e.“footed”, packages as well as leadless QFN and DFN packages using aflexible block mold process. In contrast, the conventional saw or punchtype QFN process can only manufacture leadless packages—packagesincompatible with low cost wave-solder based PCB factories.

Simply by changing the location and scanning of the lasers, one commonmanufacturing line can fabricate a wide variety of street and capsuleedge designs for footed and leadless packages. For example, in FIG. 11C,an alternate capsule edge design where plastic covers the sidewalls ofthe Z-shaped leads 100G is possible. Starting with the samecross-sectional view 120 after molding laser 130A is used to removeplastic from the street and exposing the foot portion of conductivecopper 128A but not the vertical sidewall of Z-shape geometry 100G(view125). Laser 130B then cuts the portion of conductor 128A in the streetbut preserves a foot of conductive lead 128B in die-A and a foot ofconductive lead 128C in die-B (view 126).

As illustrated in FIG. 12A, by controlling the lateral energy profile oflaser 130B, the resulting shape of the feet of conductive leads 128B and128C can be adjusted. For example if a square energy profile 136 ofenergy E versus position y shown in graph 135 is used, the resultingfeet will retain a square shape. If however, a smooth-edged energyprofile 138 shown in graph 137 is used, the edges of the feet of leads128B and 128C will be rounded 129, facilitating easier solder wickingduring PCB assembly. The energy E is a combination of the average pulsepower and the number of repetitive scans rastered across the samelocation. More scans in the same location, higher power during lasing,longer pulse durations or higher duty factors increase the deliveredenergy while fewer scans, lower power, shorter pulses or lower dutyfactors decrease the delivered energy. By controlling the power andenergy the removal of metal ions by the laser is a controllableparameter, a benefit not possible using prior art punch and sawingtechniques.

As stated previously, black plastic used in semiconductor packaging isreadily absorbed by the entire spectrum of light wavelengths rangingfrom UV to infrared. Copper and other yellow metals, however, reflectvarious wavelengths, poorly absorbing the impinging laser beam. Inmanufacturing, poor laser absorption causes a large number of scansresulting in a low UPH throughput. Reflection is also dangerous, riskingdamage to the laser head from the reflected beam, and in badly designedequipment even posing a safety hazard to operators.

FIG. 12B illustrates the absorption spectra, i.e. a plot of absorptionon the y-axis versus light wavelength on the x-axis, for a variety ofcommon metals. Infrared lasers such as CO₂ gas laser wavelength 141A at10.6 μm and YAG fiber laser wavelength 141B at 1064 nm are contrasted tovisible solid-state laser wavelength 141C at 532 nm and UV solid-statelaser wavelength 141D at 355 nm. As shown, steel and iron (Fe) areeasily absorbed in the infrared spectra over In contrast, yellow metalsincluding copper 140, gold, and silver absorb poorly in the infrared,with high absorption of light shorter than 600 nm, i.e. in the UV andshort visible spectrum. Using this graph, the USMP process can beoptimized whereby

-   -   Plastic is removed using infrared laser over 1 μm, e.g. with a        YAG fiber laser at 1064 nm, resulting in evaporation of plastic        with minimal absorption by the underlying copper leadframe    -   Metal is removed for defining package feet, singulating die, and        de-junking of tie bars using a solid state UV or visible light        laser having a wavelength shorter than 600 nm, e.g. a        yellow-orange laser at 593.5 nm, green at 532 nm, blue at 473        nm, blue-violet at 405 nm, or ultraviolet lasers at either 375        nm, 355 nm, 320 nm, or 266 nm.

Using precision servo-controlled mirrors at a sufficient distance fromthe stage holding the leadframe to be processed commercially, availablelasers are able to cover large areas without moving the laser head orthe stage. So although it is possible to process a leadframe in blocksand then advance the stage mechanically, it is not necessary. Byscanning the beam in accordance with USMP method, after loading, anentire leadframe 80 mm by 250 mm can be processed without moving thelaser head or the stage. Laser processing of a leadframe is illustratedin FIG. 12C where laser head 142 scans a laser beam across leadframe 105comprising copper leadframe 108 and three block molds comprising plasticblocks 110A, 110B and 110C. The intervening regions 107 represent thesupport rails 107 of the leadframe.

In the example shown, each block is lased in succession, starting withblock 110A processed by laser scan 143A, secondly with block 110Bprocessed by laser scan 143B, and lastly for block 110C processed bylaser scan 143C. If different types of lasers are employed for plasticand copper removal, it is necessary to unload the processed leadframefrom one laser first for plastic removal and transfer it to another forlead definition, copper removal, singulation, and tie bar de-junking. Sothe entire process of laser patterning each block mold in successionwill occur twice, once for plastic removal, and a second time for metalremoval.

The size of a block is arbitrary, based on providing adequate mechanicalsupport to the leadframe with rails and cross-rails to prevent saggingor bowing of the leadframe during manufacturing and handling. While thenumber of blocks may vary from 1 to any number, typically 3 to 12 blocksare sufficient to provide adequate support yet manufacture most packagetypes with a large number of units per leadframe. If the blocks are toosmall, the block may not be an even increment of the package dimension,i.e. pitch, and useful leadframe area will be lost. Each block may takefrom 1 to 15 minutes to process depending on the size of the block andthe pitch of the package being fabricated. Finer pitch packages containmore streets and take more time to process. Nominally, one leadframe canbe processed in 10 to 20 minutes.

Aside from selecting the proper wavelength lasers for plastic and copperremoval, the USMP manufacturing process can be optimized by the scanningalgorithm employed in street fabrication. Rastering the laser beam byrows in a manner used by DLP movie projection and LCD TVs is aninefficient method because most of the leadframe retains plastic anddoes not require laser processing. Instead it is preferable to processonly the areas requiring lasing, for example by lasing the horizontalstreets first as shown in FIG. 12D, then lasing the vertical streets asillustrated in FIG. 12E. Leadframe 105 illustrates a footed package with12 feet, three on a side. During plastic removal beam scan 130A removesplastic in the horizontal streets; then beam scan 130C removes theplastic in the vertical streets. After plastic removal, in a similarmanner laser removal occurs orthogonally where beam scan 130B removescopper in the horizontal streets; then beam scan 130D removes the copperin the vertical streets.

As described previously, in the USMP process the difference in the widthof the plastic removal beam scan 130A and the copper removal beam width130B determines the length of the package's feet. Each laser scanactually comprises multiple horizontally displaced “slices” of thematerial being scanned. For example as shown FIG. 12F, plastic removalbeam 130A comprises 10 separate scans 145A through 145J, and lasercopper removal beam 130B comprises 7 separate scans 144A through 144G,each comprising a laser beam having a spot size 146 of 44 μm. Whilesmaller spots are possible, spots of 20 μm to 50 μm are preferable toreduce the number of slices required in laser scanning. Too large a spotsize, however, is not preferred because it limits a package's featureresolution. The slices can overlap slightly without any adverse effect,and in fact it is preferable to have them overlap slightly. With nooverlap, seven slices each 44 μm wide would result in a plastic cut 308μm but the total width of copper removal beam 130B is only 300 μm.Non-overlapping laser beams are problematic as residual metal andplastic and metal may survive the street fabrication process and resultin defective product.

The resulting footed package from leadframe 105 is shown in FIG. 12Gcomprising laser-defined plastic body 110Z and conductive feet 147. Forreference, the locations of horizontal laser copper removal beams 130Band vertical laser copper removal beams 130D are included.

In manufacturing four sided footed packages special consideration mustbe given to how to remove tie bars during lead formation andsingulation. Tie bars (exemplified by tie bar 148 in FIGS. 12G and 12H),extra pieces of metal used to stabilize the leadframe and to hold thedie pad in place during manufacturing naturally protrude from thepackage's plastic body. In conventional leaded packages, tie bars aremechanically clipped off and the extra pieces metal removed, i.e.“de-junked” during the singulation process. The process, whileapplicable to the USMP is not preferred because it adds mechanicalstress during the manufacturing process, requires additional equipment,and oftentimes results in a small protrusion of metal outside of theplastic potentially as shown in DPAK perspective view 45J shown in FIG.3I.

In the USMP process for fabricating four-sided footed packages, therectilinear laser algorithm comprising horizontal and vertical slicesresults in an unwanted artifact, a remaining segment of tie bar 148,which forms a copper cantilever protruding from the die pad's corners.This artifact can be eliminated using the same laser process byaugmenting the laser scan pattern. As shown in FIG. 12H augmenting thecombination of horizontal laser slices 144A through 144G to includeextra slices 149A through 149D removes the tie bar 148 artifact. Toprotect the package plastic from the laser, this laser scan is notcontinuous, but lasing occurs only for a short duration so as to directthe laser beam only at the top of tie bar 148. Alternatively, tie barremoval can occur as a step that is separate from the formation of themetal feet.

Concurrent Fabrication of Footed, Power, and Leadless Packages Inaccordance with the USMP process and packages disclosed herein, bothleaded and leadless packages can be fabricated on the same manufacturingline, even concurrently. A block diagram flow chart of the manufacturingprocess is shown in FIG. 13 comprising the steps starting with apatterned leadframe (step 150) fabricated in a manner disclosedpreviously in this application, followed by solder or epoxy die attach(step 151), optional clip lead attach process (step 152) and wirebonding (step 154). As shown by path 153, clip-lead process (step 152)may be skipped if the semiconductor is not a high current discretedevice. After wire bonding, plastic-molding (step 155) is performedusing either separate mold cavities or preferably using block molding,i.e. one mold sheet encapsulating many devices. Following molding, laserplastic and lead definition, singulation (step 159) is performed,comprising selective plastic removal using a laser (step 156), followedby laser lead definition (step 157) and tie bar cutting (step 158). Thesingulated dice are then ready for a pick and place machine to performtesting and packing onto tape and real or waffle packs as required.

FIG. 14A through FIG. 14J illustrates the concurrent fabrication of aleaded power package, specifically a footed power package, and an ICpackage comprising either a footed or leadless package using the sameUSMP process. Provided that a leadframe of the same thickness is usedfor both leaded and leadless devices, the same USMP process is capableof simultaneously fabricating these dissimilar package types on a commonline simply by changing the leadframe design. No other change inprocessing or mechanical tooling is needed. If the leadframe thicknessand plastic mold cavity thickness is changed, etch times must beadjusted accordingly.

FIG. 14A illustrates a cross-sectional view of two copper sheets, coppersheet 170A shown as the upper illustration used for fabricating a footedpower device package and, copper sheet 170B shown as the lowerillustration used for manufacturing either a leadless or footed ICpackage using the USMP method in accordance with this invention. For thesake of illustration, the dotted lines identify the vertical column100A, later used to form the package's die pad, the L-shaped geometry100F used to form the foot to a power package's heat tab, the Z shapedgeometry 100G used to form the packages' conductive leads and feet, andthe etched geometry 101R used to electrically separate the packages'conductive leads from their die pads. The thickness of copper sheet 170Acan vary from 200 μm to 700 μm, with 500 μm being a common thickness forgood heat spreading. The thickness of copper sheet 170B can vary from 50μm for smart card applications to 300 μm for power ICs, with 200 μmbeing a common thickness for most integrated circuits.

The upper figure of FIG. 14B illustrates backside etching of coppersheet 170A during leadframe fabrication of a footed power package, wheremask 171A comprising photoresist or chemical etch resistant coating withwindow 172A open to define area for copper etching. Similarly the lowerfigure of FIG. 14B illustrates backside etching of copper sheet 170Bduring leadframe fabrication of a leadless or footed IC package, wheremask 171B comprising photoresist or chemical etch resistant coatingincludes windows 172B and 172C open to define area for copper etching.The copper is then etched through windows 172A, 172B and 172C using wetchemicals or dry etching as described previously.

The upper figure of FIG. 14C illustrates copper sheet 170A duringleadframe fabrication of a footed power package just prior to front-sideetching. As shown copper sheet 170A includes backside etched cavity 173Aresulting from the previous backside etch step, coinciding with maskwindow 172A (FIG. 14B). To define areas for front-side copper etching,mask 174A comprising photoresist or chemical etch resistant coatingincluding windows 175A, 175B, and 175C. Similarly, the lower figure ofFIG. 14C illustrates copper sheet 170B during leadframe fabrication of aleadless or footed IC package just prior to front-side etching,including backside etched cavities 173B and 173C resulting from thebackside etch process corresponding to previous backside mask features172B and 172C (FIG. 14B). To define the area for front-side copperetching, mask 174B comprising photoresist or chemical etch-resistantcoating includes windows 175D, 175E, 175F and 175G.

After masking, the copper is then etched through windows 175A through175G using wet chemicals or dry etching as described previously. Whilethe etching sequence is shown with backside etching occurring beforefront-side etching, the sequence may be reversed without changing theresultant leadframe. Regardless of the sequence, the resultant leadframeis illustrated in FIG. 14D in the top illustration for the footed powerpackage, and for the bottom illustration for a leadless of footed ICpackage. After front-side copper etching, mask window 175A, 175C, 175Dand 175G results in corresponding feet 183A, 183B, 183C and 183D alsoconnecting to other devices in the leadframe to facilitate mechanicalsupport.

Also during front-side etching, openings 175B, 175E, and 175F merge withbackside etched cavities 173A, 173B and 173C (FIG. 14C) to form gaps185A, 185B and 185C, cantilever leads 181A, 181B, and 181C, verticalcolumns 182A, 182B, and 182C and backside cavities 184A, 184B and 184C.The combination of cantilever 181A, vertical column 182A and foot 183Bform the aforementioned Z-shape geometry 100G characteristic of anindependent conductive lead electrically disconnected from die pad 180Aby gap 185A in a footed power package made in accordance with the USMPprocess and design.

In an IC package, the combination of cantilever 181B with verticalcolumn 182B and foot 183C, and similarly the combination of cantilever181C with vertical column 182C and foot 183D, form the sameaforementioned Z-shape geometry 100G characteristic of an independentconductive lead electrically disconnected from die pad 180B bycorresponding gaps 185B and 185C. While the various leadframe elementsin the drawing appear independent from one another, they are allattached to one another as part of a single interconnected leadframethrough feet 183A, 183B, 183C, and 183D and other copper pieces notvisible in this specific cross section. The feet in turn connect toleadframe rails to secure the entire structure mechanically forprocessing. In the case of die pad 180B not connected to any conductiveleads or feet, the die pad must be held in place through the use oftemporary tie bars constructed as cantilevers similar to geometry 100Eand cut flush with the package's plastic during singulation.

In FIG. 14E, semiconductor die 190A, comprising a power device or powerIC is attached to die pad 180A by conductive epoxy or solder 191A whilesemiconductor die 190B comprising an IC is attached to die pad 180Bthrough conductive or non-conductive epoxy layer 191B. Unless a deviceconducts current vertically through the backside of a semiconductor die,it is undesirable to employ solder as a die attach material because thesemiconductor die requires backside metal applied to the wafer'sbackside during fabrication after thinning, adding unnecessary extracost and complexity into the semiconductor fabrication process.

In FIG. 14F, bond wire 195A connects semiconductor die 190A tocantilever 181A; bond wire 195B connects semiconductor die 190B tocantilever 181B, while bond wire 195C connects semiconductor die 190B tocantilever 181C. Other bond wires connect to other conductive leads andfeet but are not visible in this particular cross section. While, asshown, more than one bond wire may be attached to the same surface of asemiconductor, the electrical potential, signal or electrode contactedby the bond wire may be the same or may be distinct and different. Inthe case of power devices conducting very high currents, bond wires maybe replaced by a copper clip lead as described previously.

In FIG. 14G, the leadframe is molded with plastic 196A and 196B.Depending on the mold cavity tool, the plastic may be molded around eachseparate die or preferably using one to five large blocks of plasticcontaining more than one product per block. Depending on the product'sdie and package size, the number of products fabricated from one commonblock mold could range from a few units to thousands. In a block moldthe plastic covers the entire block including the street and die edgesatop feet 18A, 183V, 183C and 183D as well as filling backside cavities184A, 184B, and 184C and gaps 185A, 185B, and 185C. The thickness of theplastic must also be sufficiently thick to fully cover and encapsulateany bond wires 195A, 195B and 195C or any copper clip leads.

In the step of laser plastic removal shown in FIG. 14H, laser beam 198Ais scanned to selectively remove portions of plastic 196A and 196B. Inthe case of a footed power package shown in the upper illustration, theplastic is removed over metal sections atop feet 183A and 183B, over aportion of die pad 180A herein referred to as heat tab 180C, andexposing a small portion of vertical column 182A. In the case of aleadless or footed IC package shown in the lower illustration, theplastic is removed over metal sections atop feet 183A and 183B, theremoval area extending onto and exposing a small portion of verticalcolumns 182B and 182C.

In the case of laser plastic removal on a block mold, the laser and notthe mold cavity tool define the lateral dimensions of the packageplastic. For example, using different leadframes, a single block moldcan be used to fabricate a range of products comprising IC packages at2×2 mm, 3×3 mm, 6×6 mm, 2×3 mm, 3×5 mm or any package shape with leadson two or more sides, or to produce discrete transistor and powerpackages such as the SOT23, DPAK, and D2PAK. Alternatively, if a productspecific mold is employed, the step of laser plastic removal can beskipped or used to augment the design after molding for purposes ofpackage customization. Provided that the thickness of the plasticthickness 196C and 196D the same laser settings can be used forfabricating both IC and power packages. If, however, the power devicehas thicker plastic than the IC package, then the power setting forlaser plastic removal of the power package must be increasedaccordingly.

Finally, as shown in FIG. 14I, in the step of laser lead definition andsingulation, laser beam 199A is used to remove metal feet 183A, 183B,183C and 183D from the street and to form wave-solder compatible feet ofcontrolled lateral length and shape. For example, in the footed powerpackage in the upper illustration, the length of foot 183F and others(not shown) is defined by laser beam 199A. Also foot 183E extending fromheat tab 180C is defined by the same laser beam 199A. Similarly in theIC package shown in the lower illustration as a footed package, laserbeam 199A is used to remove all metal from the street and to define thelength of feet 183G and 183H. Alternatively, if a mechanical saw orpunch is employed, the laser lead definition and singulation can beeliminated by its mechanical equivalent. While compatible with the USMPprocess flow, mechanical solutions are inferior since they result in diestress leading to plastic cracking and residue, i.e. plastic flash thatmust be etched off Mechanical solutions are also subject to mechanicalwear, resulting in variability in the foot length.

Provided that the thickness of feet 183E and 183F is the same as thethickness of feet 183G and 183H, the same laser settings can be used forfabricating both IC and power packages. If, however, the power devicehas thicker metal feet than the IC package, then the power setting forthe laser cutting of the metal feet in the power package must beincreased accordingly.

Using lasers offers significant advantages over today's conventionalmechanical methods because it enables footed and leadless packages to befabricated in the same manufacturing line. In the universal surfacemount package flow as described, a leaded or leadless package isdetermined by the relative position of the lasers for plastic removaland metal definition. For example if the width of the cut made by laserbeam 199A is smaller than the width of the cut made by laser beam 198A,then a footed package will result whereby metal feet extend laterallybeyond the plastic edge. If, however, the edges of the respective cutsmade by laser beams 198A and 199A are aligned, the plastic and metalwill exhibit a vertically aligned flush sidewall with no metalprotrusions.

In this manner, the lower illustration shown in FIG. 14I can beconverted from a footed package into a leadless package simply bychanging the scanning locations of laser beams 198A and 199A, as shownin FIG. 14J.

USMP Packages The universal surface mount package technology and processdisclosed herein facilitates a flexible and diverse range of packagetypes comprising both leadless and footed packages including footed ICpackages, footed power IC packages, and footed discrete power packages.Footed USMP IC packages and footed USMP power IC packages share thecommon feature of having multiple electrical connections or “feet” butdiffer in the fact that the semiconductor die contained in an IC packagenormally comprises analog, digital, memory, or microcontroller functionsthat generally do not carry high current or dissipate substantialamounts of power while power IC packages contain semiconductor dice thatdo.

Power IC semiconductor dice include analog and/or digital controlcircuitry combined with arrays of one or more high-voltage orhigh-current switches, voltage regulators, switching power supplies,current limiters, motor drivers, solenoid drivers, lamp and LED drivers,and other interface products. While in some cases, the footed USMP ICpackages may be used for both power and non-power applications, in othercases, power IC specific USMP packages may also be realized by any of avariety of techniques including:

-   -   Increasing the heat sinking and heat spreading capability of the        USMP package by using thicker leadframes, exposed die pads, and        heat tabs soldered to a PCB    -   Reducing on-resistance by eliminating bond wires using clip        leads or flip-chip assembly methods    -   Reducing thermal resistance by die thinning and conductive epoxy        die attach

Discrete power devices require the same low thermal and electricalresistance as power ICs and employ the same techniques as describedabove, except the power discrete devices generally conduct highercurrents and lower electrical resistances than their power ICcounterparts, achieved using clip leads, larger diameter bond wires, ora greater number of bond wires. Discrete transistor and power packagesgenerally require 2 to 7 electrical connections, with three connectionsbeing the most broadly applicable, i.e. with a low current gate or inputsignal, a high current source or cathode connection connected throughbond wires or clip leads, and a drain or anode connection made throughthe electrically conductive die pad that also serves as a heat sink.

In addition to manufacturing footed and leadless packages, the USMPprocess and technology disclosed herein is also capable of fabricatingleaded packages either for thru-hole or surface mount assembly. Themajor difference between a footed package and a leaded packagefabricated with the USMP process is best illustrated through crosssectional views of various types of USMP packages. The cross sectionsshown in FIG. 15A through FIG. 15F represent a cutline from any packageedge having leads, feet or connections, through the package to theopposing edge.

FIG. 15A contrasts a footed and leadless USMP fabricated package, eachhaving a lateral length on a PCB extending from Y0 to Y10. Footedpackage 220A and leadless package 220B include conductive feet 183G and183H comprising segments B, vertical columns 182B and 182C comprisingsegments A, cantilevers 181B and 181C comprising segments C, exposed diepad 180B comprising segment A, and an intervening gap between segment Aand segments C. Semiconductor die 190B sits atop exposed die pad 180B,attached by intervening die attach 191B. Bond wire 195B electricallyattaches to an electrode on a portion of the surface of semiconductordie 190B and connects through cantilever 181B to foot 183G. Bond wire195C electrically attaches to another electrode on a portion of thesurface of semiconductor die 190B and connects through cantilever 181Cto foot 183H.

The bottoms of segments A and B are intrinsically coplanar beingconstructed from a common piece of copper. The tops of segments A and Care intrinsically coplanar being constructed from a common piece ofcopper. Outside of the die in the street, i.e. laterally at locationsbelow Y0 or beyond Y10, segment D is clear of all plastic and metal. Inleadless package 220B, laser-defined plastic 196E extends laterally fromstreet to street, i.e. from Y0 to Y10. In the case of footed package220A, plastic 196D does not cover the package from street-to-street, butinstead extends laterally from Y2 to Y8 atop vertical columns 182B and182C, with only a portion of the vertical columns being visible beyondthe edges of plastic 196D. Plastic 196D and 196E both extend verticallyfrom the bottom edge of the plastic to an upper surface covering bondwires 195B and 195C. In manufacturing, both footed package 220A andleadless package 220B are fabricated identically except the laser usedto remove the plastic defines the lateral extent of plastic 196D infooted package 220A between Y2 and Y8 while the lateral extent ofplastic 196E in leadless package 220B remains undisturbed between Y0 andY10.

FIG. 15B illustrates two variants of leadless and footed USMP packagesmade in accordance with this invention. In footed package 220C, plastic196F extends from Y1 to Y9 extending atop feet 183G and 183H andcompletely encapsulating vertical columns 182B and 182C. In leadlesspackage 220D, the foot previously comprising segments B is replaced byvertical columns 182D and 182E comprising segments A.

FIG. 15C illustrates a footed USMP package 220E and a leadless package220F comprising isolated die pads made in accordance with thisinvention, specifically where die pad 181D comprises segment Cencapsulated on all sides by plastic 196D or 196E.

FIG. 15D illustrates two variants of power USMP packages made inaccordance with this invention. In footed power package 220G, asemiconductor die 190A comprises a power device mounted atop an exposeddie pad 180A encapsulated by plastic 196C, with a conductive die attach191A. Bond wire 195A electrically connects surface metallization ofsemiconductor die 190A to cantilever 181A and through vertical column182A to foot 183H. Exposed die pad 180A and heat tab 180C, along withfoot 183J, provide both electrical and thermal conduction. Plastic 196Cextends laterally from Y3 to Y9, with plastic between Y0 and Y3 removedfrom heat tab 180C to improve convective cooling.

Also shown in FIG. 15D, power package 220H includes semiconductor die190A mounted atop an isolated die pad 181E in segment C and encapsulatedby plastic 196C. Thermal energy flows laterally through isolated die pad181E to exposed die pad 181F and through vertical column 182F into foot183H. In this manner heat is removed by convection from the surface ofheat tab 181F and by thermal conduction into the PCB through foot 183K.

Although the USMP process disclosed herein is capable of fabricatingsurface mount packages with intrinsically coplanar die pad and feet, theprocess is also capable of producing leaded packages for eitherthru-hole or surface mount PCB assembly. In such packages the cantileversegment C facilitates a lead protruding from the center of the plasticand not coplanar with the backside of an exposed die pad. FIG. 15Eillustrates one implementation of a leaded package where cantilever 181Hprotrudes from plastic 196C for an extended length from Y9 to Y20. Inthe process of fabricating package 220J, the backside mask layer has anopening that extends throughout section C whereas the topside mask layerextends throughout section C, the result being that the metal sheet isetched only from the backside in section C. As a result, the bottom ofcantilever 181H is not coplanar with the bottom of die pad 180A, heattab 180C, or heat tab foot 183J. In this way the USMP process can beemployed to produce leaded packages such as the TO-220, but withoutrequiring mechanical punching, eliminating all mechanical stress.

The USMP process can also be used to replace gull wing packages whilecompletely eliminating the need for imprecise mechanical lead bending.An example of a USMP replacement of a gull wing power package 220K isshown in FIG. 15F, where cantilever 181L extends beyond plastic 196Cfrom Y9 to Y11. Beyond Y11, vertical column 180L comprising segment Aconnects to a foot 183L extending to Y12. Unlike conventional gull wingpackages, the length of cantilever from Y9 to Y11 is not constrained bythe need to secure a clamp for mechanical lead bending. Moreover, thebottom surface of foot 183L is intrinsically coplanar with the bottom ofdie pad 108A and foot 183J because they are constructed from the samepiece of copper without any mechanical bending or punching. Noconventional lead bending process can guarantee coplanarity. While inthe embodiment shown a heat tab 180C is located on one edge of thepackage and lead 181L on the other side, leads may be present on two,three, or four sides of the package, with our without the heat tab asdesired.

The cross sections shown in the prior illustrations representcross-sectional views taken at cutlines through and in parallel toconductive leads. FIG. 16 illustrates cross-section views taken atseveral cutlines parallel to the package sides and perpendicular to theconductive leads. The perspective drawing illustrates the locations ofthe various cross sections shown, where die pad 209 is spaced apart fromcantilevers 205A and 205B by a space 208 comprising gaps. Cantilevers205A and 205B comprising segments C connect to vertical columns 203A and203B comprising segments A which in turn connect to feet 201A and 201B,which are spaced apart laterally by air gap 202. Vertical surface 210defines the lateral extent of the package's plastic, where everything infront of vertical surface 210 is exposed and everything behind it isencapsulated.

Cross section Y1-Y1′ illustrates the cutline through feet 201A and 201Bseparated by air gap 202. In the plane of vertical surface 210, crosssection Y2-Y2′ illustrates the cutline through vertical columns 203A and203B separated by plastic 204 202. Behind the plane of vertical surface210, cross section Y3-Y3′ illustrates the cutline through cantilevers205A and 205B separated by plastic 204. In gap 208 between the end ofcantilever 205A or 205B and die pad 209, cross section Y4-Y4′illustrates only plastic 204 is present.

USMP Package Features Using the USMP fabrication sequence disclosedherein a wide variety of packages types and diverse package features canbe fabricated. While the internal construction of USMP packages mayvary, the external package features relevant to PCB assembly fabricatedby the USMP process can be identified and grouped into several largetaxonomies, namely

-   -   Footed surface mount packages with exposed sidewalls    -   Footed surface mount packages with non-exposed sidewalls    -   Leadless surface mount packages    -   Leaded through hole packages with straight leads    -   Leaded surface mount (i.e. gull wing) packages (without lead        bending)    -   Heat tab power surface mountable packages    -   Combinations of the above

While the above leaded packages may also utilize lead bending andforming steps to fabricate conventional gull wing shaped leads there isno benefit to do so, as the various USMP options described above aresuperior to mechanically bent leads both in performance and inmanufacturability.

FIG. 17A illustrates perspective, lengthwise, side, and bottom views ofa footed surface mount package with exposed sidewalls. In perspectivedrawing 250, plastic package 251 includes at least one conductive foot252 protruding from the package body coplanar with the bottom of thepackage. This foot, comprising copper plated with a solderable metalsuch as tin, silver, palladium, nickel, etc. is used for soldering thepackage to a PCB and is compatible with both wave-soldering and solderreflow assembly.

In wave-solder assembly of a footed package, solder is applied fromabove after the package is affixed or glued to the PCB. The solder, inmolten form coats the package and PCB but adheres only to the metalsurfaces, i.e. to the exposed foot 252 and possibly also to the exposedsidewall 253. In wave-solder assembly, no solder is applied beneath foot252 prior to the component's placement. The resulting solder is easilyverifiable using automatic optical inspection methods to confirm aproper solder attachment has been achieved.

The footed package shown in FIG. 17A is also compatible with solderreflow assembly processes. In solder reflow assembly, solder is coatedonto the PCB prior to component placement and melted into place. Thepackage is then placed atop the hardened solder and held in place on thePCB using glue or mechanical support while the PCB is fed through afurnace or oven, typically on a slow moving conveyor belt. The oven'stemperature is chosen to be sufficiently high to re-melt the solder onthe PCB as the PCB passes through it. The melted solder then flows inliquid form adhering to the package's conductive 252 foot and possiblywetting onto the sides of the foot by the action of surface tension.Because the solder, melted onto the PCB before component placement,melts a second time, the process is referred to as a solder “reflow”assembly process. Reflow PCB assembly is slower and involves moreexpensive production equipment than wave-solder assembly. Generallywave-solder assembly requires x-ray inspection to confirm solderingquality.

The footed USMP package is unique in that it is both wave-solder andsolder reflow compatible. Specifically the package is wave-soldercompatible because the solder easily flows onto foot 253 and partiallyonto vertical sidewall 253. As shown in the bottom view however, it isevident that feet 252 comprise a conductor larger than that protrudingbeyond plastic 251. This large metal pad exposed on the package'sunderside, having a total metal area equal to or greater than today'sleadless packages such as the QFN or DFN, provides sufficient area forreliable solder reflow attachment. With proper PCB design, solder duringreflow can also redistribute itself via surface tension up onto the topand sides of foot 252, facilitating optical inspection even insolder-reflow assembly lines.

FIG. 17B illustrates perspective, lengthwise, side, and bottom views ofa footed surface mount package with non-exposed vertical sidewalls. Inperspective drawing 260, plastic package 261 includes at least oneconductive foot 262 protruding from the package body coplanar with thebottom of the package but does not include a metallic vertical sidewallfor solder to wet onto. Like the previously described package, thisvariant of the footed package may be assembled onto a PCB using eitherwave-soldering or solder reflow.

Whether the vertical conductive sidewall is beneficial or not is amatter of preference for the particular PCB assembly house. Eliminatingthe vertical conductive sidewall may reduce the risk of unintendedshorts between the package's feet and any exposed tie bars but withproper design rules, the risk can completely mitigated. The advantage ofan exposed vertical sidewall is that it provides additional area forsoldering and is easily confirmed by optical inspection, but properprocessing of the foot-only package can reliably produce the sameperformance. So in essence, there is no difference between the twoversions of the footed package. Throughout the remainder of theapplication the footed package illustrations will depict packages withexposed vertical sidewalls, but it should be understood that non-exposedsidewall version may be substituted as desired.

FIG. 17C illustrates perspective, lengthwise, side, and bottom views ofa leadless surface mount package. In perspective drawing 270, plasticpackage 271 has no conductive foot or lead protruding from the packagebody and no metal for solder to reliably attach onto. The verticalconductive sidewall 273, while solderable is not adequate to insuresolderability using wave-solder assembly. So unlike the previouslydescribed footed packages, this variant of the USMP package can only beassembled onto a PCB using solder reflow. The key point of this graphicis the USMP process is capable of making exact duplicates of existingleadless packages such as the QFN and DFN using the same USMPfabrication sequence capable of making wave-solderable footed packagesand even capable of fabricating through-hole leaded packages, hence thepackage's moniker “universal”.

A variation of the USMP fabricated leadless package is shown inperspective, lengthwise, side, and bottom views in FIG. 17D. In thisversion, shown in perspective drawing 276, the leadless landing padcomprises only a foot 277 rather than an entire conductive column sothat the exposed vertical sidewall is replaced by the vertical sidewallof foot 277 contained entirely within the plastic 271 except for itssidewall and underside edges. The underside view of this variant isidentical to that of feet 275 in the previous illustration. In anotheralternative embodiment shown in FIG. 17E, foot 279 is inset from plasticbody 271 edge, and no metal appears on the package sidewall as depictedin perspective drawing 278.

An example of a leaded package manufactured using the USMP process isillustrated in FIG. 18A including perspective, lengthwise, side, andbottom views. While the package is fabricated using the USMP processdesigned for making surface mount packages, the package shown inperspective view 280 is a leaded package designed for through-hole PCBassembly, not for surface mounting. As such lead 286 protrudes frompackage body 281, near the center of the plastic package's body and notcoplanar with the bottom of the package. The shadow or optical“projection” 287 of lead 286 onto the plane defined by the bottom ofplastic 281 is shown to clarify the three dimensional location of thelead.

For completeness, the USMP process can be used to fabricate “leadedsurface mount packages” similar in shape to gull wing packages butwithout any need for lead bending. This type of package is illustratedin the perspective drawing 290 of FIG. 18B comprising metal lead 296protruding from plastic body 291 and intersecting with vertical column293 connected to foot 292. Foot 292 is precisely coplanar with thebottom of the package and plastic 291 because no bending is involved infabricating the lead. The shadow or optical “projection” 297 of lead 296onto the same plane as the bottom of plastic 291 and foot 292 is shownto clarify the three dimensional location of the lead elements.

The USMP process is also capable of fabricating heat tabs used in powerpackaging. In perspective 300 of FIG. 18C thick metal heat tab 303protrudes from plastic 301 to facilitate enhanced thermal conductioninto the PCB and enhanced convection into the air. As shown, thick metalheat tab 303 is attached to foot 302 to provide wave-soldercompatibility, a feature conventionally fabricated heat tabs do notoffer. Foot 302 may be located along one edge of heat tab 303 as shown,or may circumscribe the heat tab 303 along its periphery in its entiretyor in a portion thereof.

In summary, the visible elements of the various packages that may befabricated using the USMP process comprise the geometric elementsdescribed previously in FIG. 9A through FIG. 9D. Specifically, in footedpackages only the foot protrudes beyond the package plastic, in leadedpackages the cantilever protrudes from the plastic, in power packagesthe entire vertical column protrudes beyond the package body, while inleadless packages no metal substantially extends beyond the plastic'sexterior edge.

Internal Construction of USMP Fabricated Footed Packages To demonstratethe versatility of the USMP process in fabricating a wide range ofpackages, it is beneficial to illustrate the internal construction ofexemplary packages by the cross section. In asymmetric packages such asfooted DPAK or a footed DFN, the cross sections in the lengthwisedirection, i.e. transecting the leads, will be different than thetransverse cross sections. In a quad package, the cross sections aretypically symmetric with no differentiation between lengthwise andwidthwise orientation, except possibly for the package's length in thatdirection.

FIG. 19A comprises cross-sectional views of exposed and isolated die padUSMP leadframes in the lengthwise package direction, specifically alonga cutline through a die-pad-connected foot and an isolated foot. Theleadframe cross-sectional views are “asymmetric” with respect to animaginary center line because the leadframe features are not mirrorimages on opposite sides of the package's center, i.e. the left side andright sides are different. Cross-sectional view 340A representingcutline A-A′ illustrates an exposed die pad package where die pad 351Aconnects to foot 352A on one side while cantilever 353A, vertical column354A and foot 352B form a Z-shaped conductor and foot not connectedelectrically to die pad 351A. Plastic envelopes the leadframe andsemiconductor die (not shown) including a top portion 350A and a lowerportion 350B to realize a void-free homogeneous encapsulant. The loweredge of plastic 350B is coplanar with the bottom of feet 352A and 352B,vertical column 354A, and exposed die pad 351A. In cross section 340Crepresenting cutline C-C′ exposed die pad 351A is replaced by isolateddie pad 353A comprising a cantilever portion of the leadframe.

FIG. 19B comprises cross-sectional views of exposed and isolated die padUSMP leadframes, specifically along a symmetric cutline through die padsand tie bars. In cross section 340B representing cutline B-B′ exposeddie pad 351A includes tie bars 353C and 353D comprising cantileverportions of the leadframe, surrounding by plastic 350A and 350B. Thelateral edges of tie bars 353C and 353D do not protrude beyond the edgeof the plastic package body. The lower edge of plastic 350B is coplanarwith the bottom exposed die pad 351A. In cross section 340D representingcutline D-D′, isolated die pad 353E comprises a cantilever portion ofthe leadframe throughout the plastic body. Because the isolated die padmerges with the tie bars, they are indistinguishable in this crosssection.

FIG. 19C comprises cross-sectional views of exposed and isolated die padUSMP leadframes, specifically along a symmetric cutline throughdie-pad-connected feet. In cross section 340E representing cutline E-E′exposed die pad 351A connects to feet 352A and 352B on opposing sides ofthe package and is encapsulated on its top surface by plastic 350A. Incross section 340F representing cutline F-F′ isolated die pad 353Fconnects to feet 352A and 352B on opposing sides of the package and isencapsulated by plastic 350A above and 350B below.

FIG. 19D comprises cross-sectional views of exposed die pad USMPleadframes for power packaging, specifically representing a cutlinethrough a heat tab and feet. In cross section 340G representing cutlineG-G′ exposed die pad 351A extends beyond encapsulating plastic 350A toform heat tab 355. Foot 352A is connected to heat tab 355 to facilitatewave-solder capability. On the other edge, cantilever 353A, verticalcolumn 354A and foot 352B form a Z-shaped conductor and foot notconnected electrically to die pad 351A. Plastic envelopes the leadframeand semiconductor die (not shown) including a top portion 350A and alower portion 350B to realize a void-free homogeneous encapsulant. Incross section 340H representing cutline H-H′ exposed die pad 351Aconnects to cantilever 353G, vertical column 354B and foot 352B.Cantilever 353G sits atop plastic 350B. The bottom edge of plastic 350Bis coplanar with the bottom edge of feet 352A and 352B, exposed die pad351A, and heat tab 355.

FIG. 19E comprises a cross-sectional view of an exposed die pad USMPleadframes along a cutline through a heat tab and tie bar. In crosssection 340J representing cutline J-J′ exposed die pad 351A connects toheat tab 355 and foot 352A while on the opposing edge cantilever 353Dsitting atop plastic 350B extends laterally to the edge of plastic 350Aand 350B.

FIG. 19F comprises cross-sectional views of exposed and isolated die padUSMP leadframes along a symmetric cutline through feet not connected tothe die pad. Specifically, in cross section 340K representing cutlineK-K′, a Z-shaped conductor and foot comprising cantilever 353A, verticalcolumn 354A, and foot 352A is located adjacent to, but electricallyisolated from, exposed die pad 351A. Symmetrically, the package'sopposing edge includes another electrically isolated Z-shaped conductorand foot comprising cantilever 353B, vertical column 354B and foot 352B.Plastic envelopes the leadframe and semiconductor die (not shown)including a top portion 350A and a lower portion 350B to realize a voidfree homogeneous encapsulant. The bottom edge of plastic 350B iscoplanar with the bottom edge of feet 352A and 352B, and with isolateddie pad 353H comprises a cantilever surrounded on all sides by plastic350A and 350B. As such die pad 353H is electrically isolated from thepackage's backside and from any adjacent feet.

FIG. 19G comprises cross-sectional views of exposed and isolated die padUSMP leadframes, specifically made along a symmetric cutline through diepads not transecting feet or tie bars. For example, cross section 340Mrepresenting cutline M-M′ illustrates exposed die pad 351A surrounded byplastic 350A and 350B while cross section 340M representing cutline N-N′illustrates isolated die pad 353H surrounded by plastic 350A and 350B.

FIG. 19H comprises cross-sectional views of exposed die pad USMPleadframes along a symmetric cutline through dual die pads with andwithout tie bars. Cross section 340Q representing cutline Q-Q′illustrates two die pads, specifically exposed die pads 351A and 351Bsurrounded by plastic 350A and 350B. In cross section 340P representingcutline P-P′ the two die pads connect to cantilever tie bars extendingto the edge of the plastic body, specifically where exposed die pad 351Aconnects to tie bar 353C and where die pad 1351B connects to tie bar353D.

FIG. 19I comprises cross sectional views of isolated die pad USMPleadframes along a symmetric cutline through dual die pads with andwithout tie bars. Cross section 340S representing cutline S-S′illustrates two die pads, specifically isolated die pads 353J and 353Ksurrounded by plastic 350A and 350B. In cross section 340R representingcutline R-R′ the two die pads connect to cantilever tie bars extendingto the edge of the plastic body, but because the cantilever tie andisolated die pad are formed from the same cantilever, they areindistinguishable in the drawing.

FIG. 19J comprises cross sectional views of mixed isolated and exposeddie pad USMP leadframes along a symmetric cutline through dual die padswith and without tie bars. Cross section 340U representing cutline U-U′illustrates two die pads, specifically exposed die pad 351A and isolateddie pad 353K surrounded by plastic 350A and 350B. In cross section 340Trepresenting cutline T-T′ the two die pads connect to tie bars extendingthe edge of the plastic body. As shown, exposed die pad 351A connects totie bar 353C comprising a cantilever. Isolated die pad 353K similarlyconnects to a cantilever tie bar but since the die pad is formed fromthe same cantilever, the isolated die pad and tie bar areindistinguishable in the drawing.

FIG. 19K comprises cross sectional view 340V of a dual isolated die padUSMP leadframe, specifically depicting symmetric cutline V-V′ throughisolated dual die pads 353L and 353M, corresponding vertical columns354A and 354B, and corresponding die-pad connected feet 352A and 352B.

Lastly FIG. 19L illustrates a cross sectional and bottom view a Z-shapedconductor and foot not connected to a die pad comprising a cantileverportion 353A used for wire bonding, a vertical column 354A, and a foot352B. From both bottom and cross sectional views the exposed metal onthe backside of the package includes a portion overlapping plastic 350Aand another portion protruding beyond the plastic's edge. Throughoutsubsequent drawings in this disclosure, the Z-shaped conductor and footwill be represented as a shaded foot depicting that portion of theconnection viewable from the package's underside and a thin lineextension representing the cantilever portion located inside plastic350A and not discernable from the package's exterior, not visible fromthe package's underside, except through the use of X-ray inspection. Thelength of the dotted portion is subsequent illustrations may not be toscale but is included simply to remind the reader that the foot is partof a square Z-shaped conductor.

Examples of Dual USMP Footed Packages The following illustrations depicta variety of dual-sided package constructions that can be fabricatedwith the USMP process and methods disclosed herein. A dual package is apackage where leads or feet are present on opposing sides of thepackage. Dual packages may be square or rectangular. In a rectangularpackage, the longer dimension is referred to as the lengthwise directionof the package whether it has connections, i.e. leads or feet, on thoseedges or orthogonal to those edges. The drawings generally include aperspective illustration of the package and two undersideillustrations—one using an exposed die pad, the other comprising anisolated version of the same package. In most cases the perspective viewis identical for both the exposed die pad and isolated versions.

The relevant cross sectional cutlines from the previous section areidentified on the underside views to unambiguously identify eachpackage's construction. Moreover, using the USMP process any footeddual-sided package can be converted into a dual leadless package, i.e. aDFN equivalent footprint having no feet extending beyond the plasticbody's edges, simply by aligning the laser cuts for the metal removal tothe same regions and edges used to define plastic removal. For the sakeof brevity, the USMP leadless versions of the following dual packageswill be excluded from the drawings.

FIG. 20A through FIG. 31 illustrate the extremely diverse range ofsingle-die and multi-die packages that can be fabricated using USMPmethods and apparatus disclosed herein as depicted by topside,underside, and in some cases by perspective views. For thesingle-die-pad packages the labeled cross-sectional views correspond tothe similarly labeled detailed cross-sectional constructions shown inFIG. 19A through FIG. 19G (i.e., cutlines A-A′, B-B′ . . . N-N′), andfor the multi-die-pad packages the labeled cross-sectional viewscorrespond to the similarly labeled detailed cross-sectionalconstructions in the detailed cross sectional constructions shown inFIG. 19H through FIG. 19K (i.e., cutlines P-P′, Q-Q′ . . . V-V′) and inFIG. 24C through FIG. 24J (i.e., cutlines W1-W1′, W2-W2′ . . . Z4-Z4′).A detailed comparison of the topside and cross sectional view of aZ-shaped conductor and foot is also included in FIG. 19L.

The drawings included are schematic representations of the various USMPfabricated packages and their elements, not dimensionally precise CADdrawings. While the general dimensions of the drawings are intended tobe accurate, in many cases the exact dimensions are not preciselyconsistent, e.g. the length of the cantilever section of the Z shapedconductor and foot may be longer than depicted by underside viewdrawings. As such these drawings are intended to illustrate USMPelemental components, e.g. a package's die pad, foot or feet, Z shapedconductors, cantilever extensions, and tie bars without limitation. Itwill be well known to those skilled in the art that dimensions may beincreased or reduced without affecting the general features madepossible by the USMP fabrication process.

As shown, FIG. 20A comprises various views of single-die-pad 2-footedUSMP 370 compatible shown with either isolated or exposed die pads. Suchpackages are useful for packaging devices with two electricalconnections such as semiconductor diodes including PN, zener, andSchottky diodes, transient voltage suppressors, voltage clamps, currentlimiters, and other two-terminal devices. The footed package as showncomprises plastic 371, foot 372, and wide foot 373. Tie bars 374 and thepackage feet connect to the leadframe matrix, holding the packagesecurely in place during manufacturing.

In the illustration in the lower left, in order to maximize theavailable die size and to lower the package's thermal resistance,exposed die pad 376 is connected to wide foot 373 as depicted alongcutline A-A′ and illustrated previously in FIG. 19A. A cross section ofthe tie bar connection perpendicular to cutline A-A′ is depicted alongcutline B-B′ corresponding to the cross-sectional view shown previouslyin FIG. 19B. Similarly, in the illustration in the lower right, tomaximize the die size, wide foot 373 is connected to isolated die pad377 as depicted along cutline C-C′ and along tie bar cutline D-D′corresponding to the cross-sectional views shown previously in FIG. 19Aand in FIG. 19B respectively. While the thermal resistance of theisolated package of the isolated die pad package is not as low as theexposed die pad version, substantial heat conduction flows through thecantilever die pad, down to die-pad connected foot, and into the PCB.

A variant of the previous single-die-pad 2-footed USMP 380 isillustrated in FIG. 20B where the second isolated foot 382 is made aswide as the die pad connected foot 383. The cross sections are identicalto the previous illustration. FIG. 20C further expands the maximum diesize of the package by extending the die pad connected foot onto threesides of the package, eliminating the tie bar by the three-side footdesign. For example, in the exposed die-pad version shown in the lowerleft illustration, exposed die pad 396 connects to foot 393 on threesides.

Although the lengthwise cross section depicted by cutline A-A′ remainsunchanged from the prior versions, the widthwise cross section isdifferent, as represented along cutline E-E′ as depicted by thecorresponding cross section shown previously in FIG. 19C. Similarly, theisolated die pad version of the same package is illustrated in the lowerright drawing where three-sided foot 393 connects to isolated die pad397. Although the lengthwise cross section depicted along cutline C-C′shown previously in the cross section of FIG. 19A remains unchanged fromthe prior versions, the widthwise cross section is different, asrepresented along cutline F-F′ as depicted by the corresponding crosssection shown previously in FIG. 19C. In another embodiment of the same2-footed package the three-sided foot is combined with a wide foot 402as shown in drawings of FIG. 20D.

The size of the aforementioned USMP footed packages with two electricalconnections can be adjusted based on the current rating and die size ofthe product being packaged. For large area die conducting highercurrents, multiple bond wires, flip chip assembly, or copper clip leadsmay be used to connect the die's topside to the other connection. Fordevices expected to dissipate substantial heat, the exposed die padversion is preferred because of its lower thermal resistance and betterheat spreading capability.

FIG. 21A comprises various views of single die pad 3-footed USMP 410compatible with either isolated or exposed die pads. Such packages areuseful for packaging devices with three electrical connections such asbipolar transistors, small signal MOSFETs, JFETs, power MOSFETs,high-voltage MOSFETs, three-terminal voltage regulator ICs, low-dropoutlinear voltage regulators or LDOs, and shunt regulators, or any threeterminal device provided it does not exhibit excessive heat generation.High power devices such as thyristors and IGBTs generally require apower package with a heat tab and are therefore not candidates for usingthis particular class of footed USMPs.

The footed package as shown comprises plastic 411, feet 412A and 412B,and wide foot 413. Tie bars 414 and the package feet connect to theleadframe matrix, holding the package securely in place duringmanufacturing. In the illustration in the lower left, in order tomaximize the available die size and to lower the package's thermalresistance, exposed die pad 416 is connected to wide foot 413 asdepicted along cutline A-A′ and shown previously in FIG. 19A. A crosssection of the tie bar connection perpendicular to cutline A-A′ isdepicted along cutline B-B′ as shown previously in FIG. 19B. Similarly,in the illustration in the lower right, to maximize the die size, widefoot 413 is connected to isolated die pad 417 as depicted along cutlineC-C′ and shown previously in FIG. 19A and along tie bar cutline D-D′ asshown previously in FIG. 19B. While the thermal resistance of theisolated die pad package is not as low as the exposed die pad version,substantial heat conduction flows through the cantilever die pad, downto the die-pad connected foot, and into the PCB.

An improved thermal performance can be achieved using a three-sided footshown for USMP 420 in FIG. 21B. As shown, the maximum die size of thepackage is enlarged by extending the die pad to the package edge,eliminating the tie bar, and connecting the die pad to a foot on threesides of the package. For example in the exposed die-pad version shownin the lower left illustration, exposed die pad 426 connects to foot 423on three sides.

Although the length of the die pad 426 along cutline A-A′ shownpreviously in FIG. 19A remains unchanged from the prior versions, thewidth of the die pad 426 along cutline E-E′ depicted in FIG. 19C isgreater, i.e. wider. Similarly, the isolated die pad version of the samepackage is illustrated in the lower right drawing where three-sided foot423 connects to isolated die pad 427. Although the length of the die pad427 along cutline C-C′ with a corresponding cross section shown in FIG.19A remains unchanged from the prior versions, the width of the die pad427 along cutline F-F′ depicted in FIG. 19C is greater, i.e. wider.

At higher power levels, a heat tab is required to further improvethermal conduction and convective cooling. For example, FIG. 21Cillustrates 3-footed single die pad power USMP 430 with heat tab 438.The package includes four feet, namely 432A, 432B, 432C and 433; exposeddie pad 436 with heat tab 438 and tie bar 434. To be consistent withconventional DPAK and D2PAK designs, center foot 432B is electricallyshorted to exposed die pad as illustrated along cutline H-H′ as depictedby the corresponding cross-sectional view shown previously in FIG. 19D.Feet 432A and 432C are electrically isolated from exposed die pad 436 asdepicted along cutline G-G′ as depicted by the corresponding crosssection shown previously in FIG. 19D, with one terminal commonlyemployed as a gate signal and the other for a high current connection,e.g. the source connection of a power MOSFET. To accommodate additionalbond wires for high current conduction, cantilever 439C connected tofoot 442C is wider than its corresponding foot. Similarly, cantilever439A is wider than its corresponding foot 432A. One unique feature offooted USMP power packages as disclosed is the addition of heat tabconnected foot 433, enabling wave-solder assembly of a DPAK. In a powerpackage variant 440 shown in FIG. 21D, the center foot may be replacedby tie bar 444B along cutline J-J′ as depicted by the correspondingcross section shown previously in FIG. 19E.

For higher pin count dual sided packages applications vary. Packageswith 4 to 8 electrical connections often contain linear ICs, power ICs,interface ICs, and even dual MOSFETs, e.g. one N-channel and oneP-channel power MOSFET. For example, FIG. 22A illustrates a single diepad 4-footed USMP 500 comprising plastic body 501, feet 502A through502D, and tie bar 504. The footed package may be realized using anexposed die pad 506 as depicted along widthwise cutline K-K′ andlengthwise cutlines B-B′ and M-M′ as depicted by the correspondingcross-sectional views shown previously in FIG. 19F, FIG. 19B, and FIG.19G respectively. The footed package may also be realized using a singleisolated die pad 507 as depicted along widthwise cutline L-L′ andlengthwise cutlines D-D′ and N-N′ as depicted by the correspondingcross-sectional views shown previously in FIG. 19F, FIG. 19B, and FIG.19G respectively.

The terms “widthwise” and “lengthwise” are arbitrary descriptions ofperpendicular directions and are not intended to restrict or limit themeaning of the invention. In general, the term “length” refers towhichever direction is longer but should not be construed to limit thepackage's construction flexibility on the orientation of the leadframerelative to the plastic's shape, or the number of feet on the package'slonger or shorter edges so long that the design rules of the minimumfoot-to-foot spacing and foot to corner spacing are maintained. Theallowed foot-to-foot spacing, i.e. the pitch from the center of one footto its neighbor, varies depending on the capabilities of the PCB factorymounting the USMP rather than on its fabrication.

Inter-feet pitches may vary as required, generally adopting industrystandard lead pitch values used in today's gull wing leaded packages.Common center-to-center pitch dimensions may include 0.2 mm, 0.35 mm,0.4 mm, 0.45 mm, 0.5 mm, 0.8 mm, 1.0 mm, 1.27 mm, and 1.5 mm. In someinstances, e.g. in high voltage applications, a larger dimension may beachieved, not by introducing a new pitch, but by omitting one foot fromthe package while maintaining a standard pitch dimension for theremainder of the package's feet. For example, a USMP fabricated footedpackage with a standard foot pitch of 0.45 mm can be achieve a 0.9 mmpitch by omitting one foot from the package.

FIG. 22B illustrates a single die pad 6-footed USMP 510 comprisingplastic body 511, feet 512A through 512F, and tie bar 514. The footedpackage may be realized using an exposed die pad 516 as depicted alongwidthwise cutline K-K′ and lengthwise cutlines B-B′ and M-M′ as depictedby the corresponding cross-sectional views shown previously in FIG. 19F,FIG. 19B, and FIG. 19G respectively or with an isolated die pad 517 asdepicted along widthwise cutline L-L′ and lengthwise cutlines D-D′ andN-N′ also shown in the same referenced figures.

FIG. 22C illustrates underside views of various single die pad USMPswith exposed die pads. An 8-footed package may be realized as showncomprising exposed die pad 526 as depicted along widthwise cutline K-K′and lengthwise cutlines B-B′ and M-M′ as depicted by the correspondingcross sections shown previously in FIG. 19F, FIG. 19B, and FIG. 19Grespectively, with feet 522A through 522H, or similarly in a 12-footedpackage comprising exposed die pad 536 with feet 532A through 532H, or a18-footed package comprising exposed die pad 546 with feet 542A through542R. In the latter case where die pad widens in proportion to thepackage's length, more than one tie bar may be employed, e.g. tie bars544A and 544B.

FIG. 22D illustrates underside views of various USMPs with isolated diepads. An 8-footed package may be realized as shown comprising isolateddie pad 557 as depicted widthwise along cutline L-L′ and lengthwisealong cutlines D-D′ and N-N″ as depicted by the corresponding crosssections shown previously in FIG. 19F, FIG. 19B, and FIG. 19Grespectively, with feet 552A through 552H, or similarly in a 12-footedpackage comprising isolated die pad 567 with feet 562A through 562H, ora 18-footed package comprising isolated die pad 577 with feet 572Athrough 572R. As described previously, more than one tie bar may beemployed to stabilize wide die pads, e.g. tie bars 574A and 574B.

In USMP based technology as disclosed, a wide range of packages can befabricated using a common fabrication sequence simply by changing theleadframe design. For example a 16-footed dual sided USMP can be used torealize numerous permutations of single or dual exposed, isolated, ormixed die pads of varying sizes and pin outs. FIG. 23A illustratesunderside views of 16-footed USMPs with single and dual exposed diepads. The single die pad drawing shown on the left comprises an exposeddie pad 606 with feet 602A through 602P. As depicted along widthwisecutline K-K′ as depicted by the corresponding cross section shownpreviously in FIG. 19F, the feet are not connected to the die pad.Lengthwise construction is shown along cutline B-B′ through tie bars604A and 604B and along cutline M-M′ transecting only exposed die pad606 and plastic 601 consistent with the corresponding cross sectionsshown previously in FIG. 19B and FIG. 19G respectively.

The dual die pad version shown on the right side of FIG. 23A comprisestwo die pads, namely exposed die pad 616A held in place by tie bar 614Aand exposed die pad 616B held in place by tie bar 614B. Lengthwiseconstruction is shown along cutline P-P′ through tie bars 614A and 614Band along cutline Q-Q′ transecting only exposed die pad 606 and plastic601 consistent with the corresponding cross sections both shownpreviously in FIG. 19H. While exposed die pads can be mechanicallysupported from underneath during wire bonding, the center most ends ofdie pads 616A and 616B have no tie bar connections and are prone to moveduring manufacturing, especially during molding. To prevent thisproblem, the die pads can be connected to any one of the feet, either bya vertical column or by a cantilever. Various combinations of die padconnected feet are shown in subsequent drawings. For example, in theleft slide illustration of dual die pad package shown in FIG. 23B,exposed die pad 626A is held in place by tie bar 624 and die padconnected lead 622F. Exposed die pad 626B is held in place by tie bar624B and die pad connected feet 622B, 622C and 622D, also serving as anelectrical connection and a thermal path.

When leads are connected to a die pad, the maximum number of electricalconnections of a package is reduced. For example, while the dual paddesign of FIG. 23A has 16 distinct feet, it offers 18 electricalconnections because die pads 616A and 616B can be electrically connectedunderneath the die pads through the PCB. In contrast, while the leftside illustration of FIG. 23B also has 16 distinct feet, it offers only14 distinct electrical connections because feet 622B, 622C, 622D and622F are electrically shorted to the die pads.

In the right side illustration of FIG. 23B four feet have merged intoone long foot 632Z while die pad connected feet 632A through 632D remaindistinct. The resulting package integrates two low thermal resistancedie pads 636A and 636B into 13 distinct feet comprising only 10 separateelectrical connections. Because of the extra wide foot 632Z, afterwave-soldering exposed die pad 636A is capable of conducting highercurrent and slightly more heat than exposed die pad 636B.

Die pad connected feet may also be employed for USMP fabricatedmulti-pin packages with isolated pads, except that extra care must betaken in leadframe design to insure stability during wire bonding andduring molding. Examples of 16-footed USMPs with dual isolated die padsare shown in the underside views of FIG. 23C. In the left sideillustration isolated die pad 647A is stabilized by tie bar 644A and644B and by die pad connected feet 642E, 642F, and 642G. As depictedalong widthwise cutline C-C′ or by its cross section in FIG. 19A, thefeet connect to die pad 647A with corresponding cantilever sections642E, 642F, and 642G. Similarly, cantilever section 649M connects foot642M to isolated die pad 647B, together with tie bars 644C and 644Dstabilizes isolated die pad 647B. The resulting USMP has 16 distinctfeet supporting up to 14 unique electrical connections

As shown in the right side illustration of FIG. 23C, added stability canbe gained by utilizing opposing feet as depicted along widthwise cutlineF-F′ and shown by its corresponding cross section in FIG. 19C, wherefoot 652D and connecting cantilever 659D, foot 652M and connectingcantilever 659M, and tie bar 654B together form a triangle supportingisolated die pad 657B. The same concept is used for isolated die pad657A comprising die pad connected wide foot 652Z, opposing foot 652Lconnected to the die pad by cantilever section 659L, which together withtie bar 654A stabilize isolated die pad 657A. Wide feet 652Z and 652Yare designed to accommodate integrating a vertical power device such asa power MOSFET where feet 652Z and 652L together conduct the die'sbackside drain current and heat while foot 652Y supports multiplebonding wires needed for bonding the die's topside high current sourceconnection.

The aforementioned concepts for isolated and exposed die pads may becombined in dual die pad packages such as those shown underside views of16-footed USMPs shown in FIG. 23D. In the left side illustration,exposed die pad 666 is connected to foot 662L with vertical column 669Land by tie bar 664A. Foot 662D with connecting cantilever 669D, opposingfoot 662M with connecting cantilever 669M, and tie bar 664B togetherform a triangle supporting isolated die pad 667. The USMP comprises 16distinct feet supporting 15 unique electrical connections.

In the right side illustration of FIG. 23D, exposed die pad 676 extendsbeyond plastic 671 to form wide foot 672Z. By merging wide foot 672Zwith die pad 676 and eliminating the required clearance of the die padwithin plastic 671, the maximum die size can be increased allowing lowerresistance devices to be packaged. Wide foot 672Y is positioned on theopposing side of the package in order to facilitate multiple bond wiresfor high current connections.

Another consideration is the minimum allowable space between exposed diepads on a PCB. Some printed circuit board manufacturers restrict theminimum allowed space between PCB landing pads especially for dieattaching components not suitable for optical inspection. This issue canbe especially problematic for dual die pad packages. One solution is tolocate the die attach locations for dual die pads at a sufficientdistance that electrical shorts are highly improbable withoutrestricting the dice's maximum available die sizes. As shown in the leftside illustration of FIG. 24A, the space between exposed die pads 686Aand 686B can be enhanced by separating the exposed die pads andreplacing the unused space with cantilever extensions 689A and 689B.

As identified along lengthwise cutlines W1-W1′ and W2-W2′ in this mannerthe distance is increased without sacrificing the maximum die size. Theconstruction of lengthwise cutlines W1-W1′ and W2-W2′ are shown in crosssection in FIG. 24C where exposed die pad 686A is attached to acantilever extension 689A spanning a portion of the intervening gapbetween it and the other exposed die pad. Similarly cantilever extension689B spans a portion of the intervening gap between exposed die pad 686Band the exposed die pad 686A. The result of these changes increases thewidth of plastic 681 and reduces the risk of PCB shorts.

As shown in the right side illustration of FIG. 24A, the space betweenthe feet 692E through 692P and die pad 696L can also be increased in thesame manner by surrounding exposed die pad 696A on three sides bycantilever extension 699A in the lengthwise direction and by cantileverextensions 699C in the widthwise direction. The space between exposeddie pad 699D and its adjacent feet, i.e. feet 692A through 692D and 692Mthrough 692P, can be increased in the same manner by surrounding exposeddie pad 696B by cantilever extension 699B in the lengthwise directionand by cantilever extensions 699D in the widthwise directions asdepicted along widthwise cutline X1-X1′. The construction at widthwisecutline X1-X1′ shown in cross section in FIG. 24E where cantileverextensions 719C increase the width of plastic 711 and reduce the risk ofa PCB short.

The left side drawing of FIG. 24B illustrates that the cantileverextensions can be asymmetric, where cantilever extension 709A connectedto exposed die pad 706A is has a length shorter than cantileverextension 709B connected to exposed die pad 706B. To support its greaterlength, cantilever extension 709B connects to foot 702M with cantileverbridge 709C. The construction at cutlines W1-W1′ and W2-W2′ in FIG. 24Bare depicted in the cross-sectional views in FIG. 24C except that thelengths of cantilever extensions 709A and 709B, referred to bycorresponding cantilever extensions 689A and 689B at cutline W2-W2′ inthe cross section of FIG. 24C, have not been adjusted to have dissimilarlengths.

In an alternative embodiment shown the right side drawing of FIG. 24Benhanced cantilever extensions 719A and 719C surround three edges ofexposed die pad 716A. Exposed die pad 716B is surrounded by cantileverextension 719B as depicted along widthwise cutline X2-X2′ shown in crosssection in FIG. 24E and by lengthwise cutlines W3-W3′ and W4-W4 shown inFIG. 24D. In both drawings the distance of exposed die pad 716B to thenearest conductor, either to feet 712I and 712G or to the other exposeddie pad 716A, is greatly increased and the width of plastic 711 issignificantly widened.

In an alternate embodiment, only one die pad is reduced in size and theother remains unchanged. Examples of this method are illustrated in FIG.24F where in cross section W2-W2′ exposed die pad 686A remains unchangedwhile exposed die pad 686B is reduced in size and connected on one edgeto cantilever extension 698B increasing the width of plastic 681. Incross section W4-W4′ exposed die pad 716A remains unchanged whileexposed die pad 716B is reduced in size and surrounded by cantileverextension 719B increasing the width of plastic 711.

USMP fabricated dual packages can also include the use of cantileverextensions also referred to herein as cantilever interconnections,cantilever beams, or cantilever beam interconnections, to improve wirebonding and package to die interconnections. Cantilever beaminterconnections facilitate improved access to hard-to-reach portions ofan IC, circumventing bonding angle limitations, minimizing bond wirelength, and reducing stray inductance and parasitic resistance. Examplesof cantilever beam interconnections are illustrated in FIG. 25A for16-footed USMPs integrating various combinations of exposed and isolateddie pads with isolated cantilever extensions.

In the left side illustration, cantilever extensions 759A, 759H, 759I,and 759P surround die pad 756, expanding available wire bond locationsto facilitate improved bonding angles. In this manner, wire bonding fromall four sides of a semiconductor die can be achieved in a dual-sidedpackage, facilitating product in a dual-sided package previouslypossible only in a quad package. To support stable wire bonding andprevent dislocation of an isolated cantilever beam during manufacturingthe beams are secured in at least two points in the package. Forexample, cantilever beam 759A is supported by tie bar 754A on one sideand connects to foot 752A on its other end. Wire bonds from cantileverbeam 754A therefore can reach semiconductor die bonding pads locatedadjacent to the bottom edge of die pad 756 that were previously notconnectible by a direct bond from foot 752A.

Similarly, cantilever beam 759H is supported by tie bar 754B on one sideand by foot 752H on its other end, cantilever beam 759I is suspendedbetween tie bar 754C and foot 752I, and cantilever beam 759P issuspended between tie bar 754D and foot 752P. Cutlines V-V′ identify thewidthwise structure of the package, while cutlines Z1-Z1′ and Y1-Y1′identify the lengthwise structure transecting and transecting the tiebars, as depicted in FIG. 24G including cantilever beam extension 759H,exposed die pad 756, and cantilever beam extension 759A In cutlineZ1-Z1′, cantilever beam extension 759I is indistinguishable by crosssection from tie bar 754C, and similarly cantilever beam extension 759Pis indistinguishable by cross section from tie bar 754D. The crosssection of cutline V-V′ shown in FIG. 19L illustrates the widthwisecross section of dual cantilever beam structure, where cantileverextension 353L connects to foot 352A through vertical column 354A, andwhere cantilever extension 353M connects to foot 352B through verticalcolumn 354B.

In the right side illustration of FIG. 25A, isolated cantilever beamextension 769B is suspended between feet 762H and 762I and furthersupported by tie bar 764B in order to facilitate easy bonding wireaccess to any semiconductor die (not shown) mounted on exposed die pad766. Although the identifying element numbers are different, the crosssectional structure of cutline F-F′ is depicted in FIG. 19C. Tofacilitate improve thermal conduction and maximize die size die pad 766is merged with feet 762Y and 762Z. Isolated die pad 767 is supported intwo points—by cantilever bridge 769A connected to foot 762N and by tiebar 764A. The lengthwise cross sections of this package and leadframeidentified by cutlines Y2-Y2′ and Z2-Z2′ are depicted in the crosssections of FIG. 24H including cantilever beam extension 769B, exposeddie pad 766, and isolated die pad 767. In cutline Z2-Z2′, cantileverbeam extension 769B is indistinguishable by cross section from tie bar764B, and isolated die pad 767 is indistinguishable by cross sectionfrom tie bar 764A.

A wide range of possible leadframes can be realized using isolatedcantilever beam extensions. For example FIG. 25B comprises undersideviews of two alternative embodiments of 16-footed USMPs integrating dualexposed die pads with isolated interconnections. The illustration on theleft comprises two die pads, i.e. exposed die pad 776 and isolated diepad 777, with an intervening isolated cantilever beam 779D suspendedbetween feet 772D and 772M identified along cutline F-F′ as depicted inFIG. 19C. The lengthwise cross sections of this package and leadframeidentified by cutlines Y3-Y3′ and Z3-Z3′ are depicted in the crosssections of FIG. 24I.

The illustration on the right side of FIG. 25B comprises two die pads,i.e. exposed die pad 786 and isolated die pad 787, with an isolatedcantilever beam 789H suspended between foot 782H and tie bar 784B at thetop of the package. A cross-sectional view of isolated cantilever beam789H is depicted by cutline C-C′ shown in FIG. 19A. The lengthwise crosssections of this package and leadframe identified by cutlines Y4-Y4′ andZ4-Z4′ are depicted in the cross sections of FIG. 24J.

While the examples and applications of isolated cantilever beamextensions shown are illustrated using 16-footed USMP designs, theconcept and method can be extended to virtually any USMP with more thanthree feet, and as such, the number of electrical connections are notlimited to the examples shown.

Examples of Quad USMP Footed Packages The following illustrations depicta variety of four-sided, i.e. quad package constructions that can befabricated with the USMP process and methods disclosed herein. A quadpackage is a package where leads or feet are present on three of foursides of the package. Quad packages may be square or rectangular. Thedrawings generally include a perspective illustration of the package andtwo underside illustrations—one using an exposed die pad version, theother comprising an isolated die pad version of the same package. Inmost cases the perspective view is identical for both the exposed diepad and isolated versions.

The relevant cross-sectional cutlines from the previous section areidentified on the underside views to unambiguously identify eachpackage's construction. Moreover, using the USMP process any footed quadpackage can be converted into a quad leadless package, i.e. a QFNequivalent footprint having no feet extending beyond the plastic body'sedges, simply by aligning the laser cuts for the metal removal to thesame regions and edges used to define plastic removal. For the sake ofbrevity, the USMP leadless versions of the following quad packages willbe excluded from the drawings.

FIG. 26A illustrates a perspective view of a 16-footed quad USMP package900 comprising plastic 911, tie bars 914A through 914C, and feet 912Athrough 912H. Inasmuch as package 900 is symmetrical, it will beunderstood that a similar tie bar and similar feet are located on theopposite, invisible sides of package 900. In short, in the squareversion shown the package feet are distributed four to a side. The tiebars are located in the corners. The package 900 may be fabricated withan isolated or exposed die pad. FIG. 26B illustrates the underside viewof the 16-footed USMP package 900 with an exposed die pad 917 where thecross sectional construction in either the lengthwise or widthwisedirection is illustrated by cutline K-K′ as shown in FIG. 19F. Incontrast, FIG. 26C illustrates the underside view of the 16-footed USMPwith an isolated pad 917 where the cross sectional construction ineither the lengthwise or widthwise direction is illustrated by cutlineL-L′ as shown in FIG. 19F.

FIG. 27A comprises underside views of various 4 and 6-footed quad USMPswith exposed die pads. In the illustration of the upper left cornerplastic 921 comprises exposed die pad 926, tie bars 924, and four feet922, located one per side. In its minimum dimension, a quad package with4 feet is not area effective and is better implemented as a dual packageshown previously. With 6 feet, the utility of a quad USMP designimproves. In the upper right hand corner, for example, exposed die pad936 is substantially larger than the previously described die pad 926.The resulting package comprising rectangular shaped plastic 931 has sixfeet 932, with two located on the package ends and two on eachlengthwise edge. The die pad size can increased by connecting two feet948 to die pad 946 shown in the lower left illustration of FIG. 27A asshown along cutline A-A′ or alternatively as shown in the lower rightillustration by connecting four feet 958A and 958A to die pad 956 asdepicted along cutline E-E′.

Extending the footed quad USMP design to higher pin counts isstraightforward as shown by the underside views of 8- and 10-footed quadUSMPs with exposed and isolated die pads illustrated in FIG. 27B. In theupper left corner illustration of an 8-footed USMP, square quad footedUSMP comprises plastic 961, exposed die pad 966, corner tie bars 964,and feet 962 located two to a side, having a cross section depictedalong cutline K-K′. In its isolated-die-pad version shown in the lowerleft illustration of the same figure, square quad footed USMP comprisesplastic 961, isolated die pad 967, corner tie bars 964, and feet 962located two to a side, having a cross section depicted along cutlineL-L′.

Extending the USMP design to rectangular 10-footed packages also shownin FIG. 27B, the upper left corner USMP comprises plastic 971, exposeddie pad 976, corner tie bars 974, and feet 972 located two on teach endand three on each side. The package has a cross section depicted alongcutline K-K′. In its isolated-die-pad version shown in the lower leftillustration of the same figure, rectangular quad footed USMP comprisesplastic 971, isolated die pad 977, corner tie bars 974, and feet 972having a cross section depicted along cutline L-L′.

The thermal performance and maximum die area of the aforementioned USMPscan be improved using die pad attached feet as illustrated in FIG. 27C.The method is applicable both for exposed and isolated die pads. In theupper left illustration, an 8-footed quad USMP comprises an exposed diepad 986 surrounded by plastic 981 connected by vertical column 988 totwo feet 982B as depicted along cross section of cutline A-A′. Theremaining feet 982A are not connected to the die pad. In the lower leftillustration of FIG. 27C, an 8-footed quad USMP comprises an isolateddie pad 987 connected by cantilever 989 to two feet 982B as depictedalong cross section of cutline C-C′. The remaining feet 982A are notconnected to the die pad.

In the upper right illustration of FIG. 27C, the 8-footed quad USMPcomprises seven feet 982 not connected to exposed die pad 996 and onewide foot 993 connected to exposed die pad 996. The corners of exposeddie pad 996 on the opposing side not connected to foot 993 include tiebars 994. Similarly the lower right illustration of FIG. 27C shows a theisolated equivalent of a 8-footed quad USMP comprising seven feet 992not connected to isolated die pad 997 and one wide foot 993 connected toisolated die pad 997. The corners of isolated die pad 997 on theopposing side not connected to foot 993 include tie bars 994.

FIG. 27D comprises underside views of 8- and 10-footedrectangular-shaped quad USMPs with exposed and isolated die pads. In theupper left illustration comprising plastic 1001, exposed die pad 1006merges into four feet 1002B while the remaining feet 1002A are isolatedfrom exposed die pad 1006. The lengthwise cross section is depictedalong symmetric cutline E-E′ while the widthwise cross section isdepicted along symmetric cutline K-K′. The resulting USMP comprises 10feet but only seven unique electrical connections. The package is thelower right is identical in construction except that isolated die pad1007 replaces exposed die pad 1002B. In yet another minor variant ofthis package is shown in the upper right illustration of FIG. 27D, wherefour pad connected feet 1002B are replaced by with two wide feet 1003 onopposing edges of the package resulting in a 8-footed USMP with sevenunique electrical connections.

While the aforementioned three versions of the package defined byplastic 1001 in FIG. 27D utilize a die pad connected to feet located onthe narrow edges of the package, for the USMP shown in the lower leftillustration isolated die pad 1007 is connected to three feet 1002Blocated instead on the longer edge of the package. The resulting USMPcomprises 10 feet with 8 unique electrical connections.

FIG. 28A comprises underside views of 12-footed square quad USMPs withexposed and isolated die pads formed within plastic 1011. In bothdrawings the die pad is connected in all four corners by tie bars 1014and surrounded by isolated feet 1012, three on each package edge. Theleft side illustration utilizes an exposed die pad 1016 while the rightside package uses an isolated die pad 1017.

FIG. 28B comprises underside views of 16-footed rectangular-shaped quadUSMPs with exposed and isolated die pads formed within plastic 1021. Inboth drawings the die pad is connected in all four corners by tie bars1024 and surrounded by isolated feet 1022, five on each long edge of thepackage and three on each short edge. The top illustration utilizes anexposed die pad 1026 while the lower package uses an isolated die pad1027.

FIG. 29A comprises an underside view of a 20-footed rectangular-shapedquad USMP formed in plastic 1031 with an exposed die pad 1036 a twentyisolated leads 1032 located with four on each end and six on each of thesides. FIG. 29B comprises an underside view of the same 20-footedrectangular-shaped quad USMP except that it utilizes an isolated die pad1037.

FIG. 30A comprises an underside view of a 48-footed quad USMP with anexposed die pad 1046 comprising plastic 1041, four tie bars 1044 locatedin the package corners, and 48 feet 1042 located with 12 feet on eachedge. FIG. 30B comprises an underside view of a 48-footed quad USMPidentical to the prior package except that it employs an isolated diepad 1047. In another embodiment, the same package with isolated die pad1047 includes four vertical columns or posts 1049A through 1049C toprovide added stability to the leadframe. The posts are spacedsufficiently far apart to avoid any risk of unintended PCB shorts toisolated die pad 1047.

Lastly, FIG. 31 illustrates that any quad multi-footed USMP package canbe integrated with an extended heat tab. As shown in perspective andunderside views, USMP 1050 includes plastic 1051, die pad connected foot1052F, eleven isolated feet 1052A through 1052E, and 1052G through1052L, extended heat tab 1058, and heat tab connected foot 1053. Thedesign marries the low inductance and high pin count capability of aUSMP IC package with the thermal dissipation capability of a USMP powerpackage, facilitating advanced power IC designs.

Advanced USMP Leadframe Designs Using the USMP process, designs, andmethods disclosed herein, leadframe features providing unique benefitsunavailable in conventional packages can be realized.

One such unique benefit is selective tie bar removal. For example, thelaser metal removal process shown in FIG. 12H is an example of aselective tie bar removal. In the example shown, rectilinear sawing ofleads unavoidably leaves an unwanted tie bar artifact, tie bar 148,which cannot be selectively removed using mechanical means such ascutting, clipping, or sawing, without the risk of damaging the plasticmold and adjacent leads. Using USMP laser street fabrication, theunwanted metal protrusions can safely be removed by laser even betweenclosely spaced adjacent feet or leads. Because the tie bar removal is anoptical process, no space is required for clamping or holding thepackage of leads in place.

Another example of selective tie bar removal is illustrated in powerpackages such as the DPAK or D2PAK. For example, in FIG. 3E the centerlead of DPAK 31Q is mechanically clipped after manufacturing, i.e. thecenter lead functions only as a tie bar and is not required by thecustomer for electrical connections. Because it is clipped mechanically,the tie bar lead unavoidably protrudes from the plastic body of thepackage. The length of this protrusion is determined by the clearanceneeded to mechanically clip the tie bar lead without damaging thepackage's plastic. The tie bar lead protrusion is connected electricallyto the package's die pad, undesirably increasing the risk of electricalshorts between the tie bar lead and the adjacent leads.

Moreover, in power devices, the die pad and package leads often arerequired to sustain a high voltage between them, commonly supporting600V and in some cases as high as 1,000 volts. Even a partial solderbridge between the electrodes can result in electrical leakage currents,circuit malfunction, and even dangerous failures. In contrast to theconventionally fabricated DPAK, using the USMP process FIG. 21Dillustrates tie bar 444B can be cut precisely flush with the packagebody, i.e. plastic 441, without any risk of mechanical damage to theplastic or bending of feet 442A and 442B.

The benefit of selective tie bar removal can be extended to multi-leadpackages enabling leadframe designs and features never before possible.For example, FIG. 32A illustrates a footed IC package made in accordancewith the USMP process, where tie bar 1104A is positioned in between twofeet 1102A and 1102B. Similarly tie bar 1104A is located between twoadjacent feet. Together with die pad connected foot 1102E, tie bars1104A and 1104B hold exposed die pad 1106 in place during manufacturing.The mechanical support during the package's fabrication is illustratedby the leadframe shown in FIG. 32B revealing tie bar 1114A connects tothe leadframes main rail 1119 while tie bar 1114B and foot 1112E extendto connect with metal cross rails 1118, together holding exposed die pad1106 in place, especially important during wire bonding and plasticmolding.

After plastic removal defines the lateral extent of plastic 1101, thepackage is then cut from the leadframe, i.e. singulated. The package maybe held temporarily in place by adhesive tape, often referred to as“blue tape,” till the cutting is complete. The risk of the packagetwisting duration singulation from mechanical sawing or punching iscompletely eliminated by employing USMP laser metal removal. As aresult, the sequence of cutting the feet or “dejunking”, i.e. removingthe tie bars is unimportant in the USMP process. In a dual pass USMPprocess, either sequence, cutting the feet then removing the tie barprotrusions or conversely removing the tie bars then cutting the feet,will provide the same result. Alternatively, both the feet and tie barsmay be removed using a single pass laser process where the laser cutsfeet, then removes tie bars, then cuts more feet in sequence based onwhatever the laser scan reaches first.

An example of a USMP dual pass laser metal foot and tie bar cuttingprocess is shown in FIG. 32C where horizontal laser scans 1121X cut andremove the metal leadframe connections across the street up to thepackage edge 1120X (i.e., the ends of the feet) and where transverselaser scans 1121Y in the vertical direction cut and remove the metalleadframe connections across the street up to the package edge definedby line 1120Y. The resulting package at this stage in the USMP processis shown in FIG. 32D where tie bars 1114A and 1114B protrude fromplastic edge 1101 by the same length as feet 1102A and 1102B. In thesecond metal removing laser pass shown in FIG. 32E, the laser isrescanned in the horizontal direction by horizontal scans 1123X toselectively remove tie bar protrusion 1124B, and again by vertical scans1123Y to selectively remove tie bar protrusion 1124A. In the dual scanprocess the laser spot 1120 can be adjusted by focus and power to cut asmaller spot than that used when clearing the street by laser scans1221X and 1121Y in the previous figures.

The resulting package 1100 shown in FIG. 32A accommodates the use of tiebars between feet, i.e. intra-lead feet tie bars, enabling stabilizationof the package's die pad without sacrificing a foot by connecting it tothe die pad just for the sake of providing mechanical support duringmanufacturing. For example, in the left side illustration of FIG. 33A,isolated die pad 1147A is stabilized not only by die-pad-connected widefoot 1142C and conventional tie bar 1144A, but also by intra-lead tiebar 1144D. Were intra-lead tie bar 1144D not employed, the corner ofisolated die pad 1147A would be unstable, exhibiting diving boardeffects during wire bonding and potentially suffering dislocation, i.e.unwanted movement and repositioning, during molding. In a similarmanner, isolated die pad 1147B is held in place by three supports,namely by die pad connected foot 1142D, conventional tie bar 1144B, andby intra-lead tie bar 1144C.

In the right side illustration of FIG. 33A, isolated die pad 1145A isstabilized by die-pad-connected wide foot 1152C, conventional tie bar1154A located on the end of the dual package having no feet, and byintra-lead tie bar 1154D located on the footed side of the package.Isolated die pad 1157B is supported by one conventional tie bar 1154Band by two intra-lead tie bars 1154C and 1154E on opposing sides,forming a stable triangle base.

Intra-lead tie bars also make advanced interconnections possible withina USMP implemented package. For example, in the lower left illustrationof FIG. 33B a 10-footed USMP contains two die pads—one exposed and theother isolated, along with an isolated intra-package interconnection.Such interconnections are valuable when a customer's PCB design requiresa specific pinout package not possible through wire bonding. As shown,exposed die pad 1166 is stabilized by conventional tie bar 1164B andintra-lead tie bar 1164C while isolated die pad 1167 is stabilized bythe support triangle comprising conventional tie bar 1164A andintra-lead tie bars 1164D and 1164E. Isolated intra-packageinterconnection 1164G connects foot 1162H on one side of the package tofoot 1162E on the opposite side of the package diagonally located nearopposite corners of exposed die pad 1166.

Intra-lead tie bars are also applicable for quad USMPs. For example, inthe upper right illustration of FIG. 33B a quad footed USMP containsexposed die pad 1176 stabilized by conventional corner tie bar 1174C andby intra-lead tie bar 1174D while isolated die pad 1177 is stabilized infour locations, namely with corner tie bars 1174A and 1174F and withintra-lead tie bars 1174B and 1174E. As described previously, even theremoval of corner tie bars using mechanical means such as employed inLQFP packages is difficult, wasting space and risking damage to thepackage's plastic body.

Using the USMP process, leadframe geometries and package features can beflexibly determined in two different ways, namely

-   -   The geometric feature can be created as part of the leadframe        fabrication process    -   The geometric feature can be created by laser ex post facto,        i.e. performing patterning by laser after molding either before        or during singulation

An example of such a geometric leadframe feature is the thermal combshown in FIG. 34A where a DPAK or D2PAK package includes plastic 1201,feet 1202A, 1202B an 1202C, tie bars 1204A, cantilever extensions 1209Aand 1209C, and exposed die pad 1206. The exposed die pad 1206 mergesinto a heat tab 1208A with a thermal comb comprising metal fingers1208B, 1208C, 208D, and 1208E. The fingers as shown are constructedusing the full leadframe thickness, i.e. a vertical column 100Aoriginally shown in FIG. 9A. The inner periphery of the fingers includesa wide serpentine foot 1203 for solder to wet onto. With its largeperiphery, the comb structure maximizes electrical thermal andelectrical conduction between the package and the PCB, improving thermalconduction. The exposed solid metal portion of the heat tab, i.e. heattab 1208A maximizes thermal convection into the air. By adjusting therelative area devoted to solid heat tab 1208A and the thermal comb, theamount of cooling through thermal conduction into the PCB and thermalconvection into the air can be adjusted by design.

FIG. 34B illustrates the case where the thermal comb is prefabricatedinto the leadframe. As shown, thermal comb fingers 1218 and theirassociated serpentine foot 1213 are extended beyond the package edgeinto cross rails 1229Y, as are the extensions of feet 1212. On theperpendicular package edges tie bars 1214 connect to rails 1229X and1229W. The package edges are defined in the lengthwise by laser cutlines1220Y defining the length of package feet 1212 and thermal comb fingers1218, and in the widthwise direction by laser cutlines 1220X cutting tiebars 1214 flush with plastic 1201. As shown in FIG. 34C, between thecutlines 1220Y numerous vertical laser scans 1221Y are employed toremove leadframe connections to the package feet and thermal combfingers. Similarly, multiple horizontal laser scans 1221X are preformedto remove tie bars between cutlines 1220X.

In another embodiment of a DPAK or D2PAK package with a thermal comb,shown in FIG. 35A, the leadframe is modified where the thermal comb1228B connected to heat-tab 1228A comprises thin metal, i.e. comprisingthe same thickness metal as feet 1212. This version facilitates easierwave soldering but contains less thermal mass than the prior version.More importantly, by employing thin “feet” metal for the thermal comb,the comb's features can be fabricated using a laser after packagemolding. The leadframe prior to singulation is illustrated in FIG. 35Billustrating extended thin metal foot 1228B. Prior to singulation, holescan be cut with the laser to form the thermal comb as shown in FIG. 35Cwhere horizontal scans 1226 remove multiple areas 1225 within thin metalextended feet 1228B. The opening dimensions can be determined by thenumber of scans and using focus to control the laser spot size 1227.

In alternative embodiment shown in FIG. 36A, the thin metal extendedfoot 1228B is patterned using a laser to open bolt-hole 1225. In amanner similar to forming a thermal comb, the fabrication process shownin FIG. 36B involves multiple overlapping horizontal scans 1226 removinga circular area 1225 within thin metal extended foot 1228B.

Advanced USMP Leadframe Processes As described previously, the USMPleadframe must be plated to improve solderability and to inhibit copperoxidation. In the USMP process, the plating may be performed at severaldifferent times and by several different methods, namely

-   -   Prior to package manufacturing during leadframe fabrication, by        “pre-plating” the leadframe over its entire surface    -   Prior to package manufacturing during leadframe fabrication, by        “pre-plating” the leadframe selectively over a portion of its        surface, sometimes referred to as “patterned leadframe plating”    -   After molding but prior to metal patterning and singulation

The various manufacturing process sequences are represented in the flowchart of FIG. 37. For the first case, pre-plating the entire leadframe,the USMP process sequence comprises leadframe formation (step 1250A),leadframe pre-plating (step 1250B), molding (step 1250C), laser plasticremoval (step 1250D) and metal patterning and singulation (step 1250E).In the second case, i.e. patterned leadframe plating (step 1252B)replaces step 1250B. In the third process option, leadframe pre-plating(step 12500B) is skipped, as indicated by dashed line 1251A, andleadframe formation (step 1250A) is immediately followed by molding(step 1250C) which is then followed by plastic removal (step 1250D).After plastic is removed from the street, the leadframe is then platedin what is referred to as “post-deflash leadframe plating” (step 1251B)followed by metal patterning and singulation 1250E. The term de-flashrefers to the removal of stray bits of plastic resulting from sawing orpunching but is not an issue with laser plastic removal.

An example of a pre-plated leadframe is shown in FIG. 38, where copperdie pad 1261 is coated on all sides by plated metal 1269 and foot 1262and cantilever 1263 as well as the vertical column connecting them arecoated by the same plated metal 1269. While pre-plated leadframes aregenerally fine for small packages, for large and high pin count packagesand power packages the packages may suffer poor adhesion anddelamination between the plastic and the plated metal. For exampleplastic 1260A may delaminate in regions 1265A and 1265B. Surface 1265Cmay also delaminate from underside plastic 1260B. Delamination in anyarea may cause a reliability failure.

By using selective plating, delamination can be avoided by preventingplating in leadframe areas sensitive to delamination risk. As shown inthe cross-sectional view of FIG. 39, regions 1269A, 1269B and 1269C areclear of selectively plated metal 1270 because plating in those regionswas intentionally inhibited. Three methods may be used for selectiveplating. In one case, a seed layer such as titanium, platinum,palladium, nickel, or various refractory metals is deposited in theareas where plating is desired. Numerous methods may be employed tocreate a selective seed layer.

-   -   The seed layer can be deposited locally through an intervening        stencil mask so that it is present only where the plating is        intended to occur. This method to form a patterned seed layer is        referred to herein as a “patterned deposition” process    -   The leadframe is coated or deposited uniformly with the seed        layer metal, then is selectively coated with a photoresist        through a patterned stencil mask, exposing only those areas        where the seed layer should be removed. After baking the        photoresist to harden it, the seed layer is then etched in an        acid that attacks the specific metal but either does not etch or        only slowly etches copper, thereby removing the exposed seed        metal. After removing the photoresist and cleaning, the        leadframe is ready for plating. This method to form a patterned        seed layer is referred to herein as an “masked etch-back”        process    -   The leadframe is coated with a photoresist through a patterned        stencil mask, depositing photoresist only on those areas where        the seed layer is to be removed. The result is a patterned        leadframe some areas open to the copper and others covered by        photoresist. After baking, the seed layer metal is deposited        atop the patterned leadframe, some metal being deposited        directly onto the copper, while in other areas the metal is        deposited atop the photoresist. Cleaning the photoresist “lifts        off” and seed metal on top of it leaving the copper leadframe        with seed metal present only where plating is intended to occur.        This method to form a patterned seed layer is referred to herein        as a “lift off” process.    -   The seed layer could be printed onto the leadframe with a        printer, dispensing seed metal in a solvent suspension that is        dried during printing by a lamp, laser, or heating block then        baked to completely evaporate the solvent. After baking the        leadframe is heated to a high temperature to bond the seed layer        metal to the copper leadframe. Only the printed areas retain the        seed layer. This method to form a patterned seed layer is        referred to herein as a “metal printing” process.        After forming the patterned seed layer, the leadframe is ready        for selective plating. The plating chemistry must be adjusted so        that in the absence of the seed layer plating does not occur on        the bare copper.

In a second method, plating is performed everywhere and selectivelyremoved by masking and etching. In a third method shown in FIG. 40,layers 1271A and 1271B of a plating inhibitor, i.e., a material thatprevents plating, such as a glass or an organic compound, issilkscreened or printed onto leadframe 1261 prior to plating. Afterplating of plated metal 1273A the inhibitor layers 1271A and 1271B arechemically removed.

Aside from leadframe plating, another valuable feature of the USMPdesign relates to soldering a power package or an exposed die pad onto aPCB. Since wave-soldering only applies solder from above the component,then there is no way to get solder beneath a large metal area using thewave-soldering process. Conversely, as described previously, the reflowPCB is expensive compared to wave-soldering. A footed package, by itselfdoes not address this issue and must instead rely on the same techniqueused for DPAK assembly today, i.e. to perform a dual-pass PCB assemblywith one pass for attaching power devices or packages with exposed diepads and another pass for wave-soldering leads onto the board.

The first pass of a dual-pass PCB assembly is shown in FIG. 41A where inthe top illustration PCB 1300 with copper traces 1301A, 1301B, and 1301Cis coated with either conductive epoxy or solder paste, e.g. solderpaste layer 1302A atop copper trace 1301A and solder paste layer 1302Batop copper trace 1301B. Copper trace 1301C, not used for a powerdevice, is left uncoated, as are most of the PCB traces. The exposed diepad package is then positioned atop the epoxy or solder paste asillustrated in the middle figure. As such, exposed die pad 1305A sitsatop solder paste layer 1302A and foot 1305B sits atop solder pastelayer 1302B. After heating in an oven, the solder paste melts andexposed die pad 1305A sinks down into the solder paste layer 1302A,which turns into molten solder. Similarly, foot 1305B sinks down intosolder paste layer 1302B, which melts into molten solder. After thesolder hardens an electrical and thermal connection to the PCB copperconductors is formed as shown in the bottom illustration. Alternatively,if a conductive epoxy is used in place of solder paste, then the packageis mechanically pushed down into the epoxy and the epoxy is left tocure. Fast set epoxies, can cure in 30 minutes to one hour.

After the solder or epoxy attach process, during wave-soldering,additional solder flows onto the top of the feet. Since thewave-soldering achieves a high-quality electrical connection between thePCB copper traces and the feet, the main purpose and benefit of thesolder paste or epoxy is to facilitate improved thermal conduction intothe PCB, not to act as the primary path for electrical conduction. Inorder to minimize the thermal resistance, the final thickness of theepoxy or solder layers 1302A and 1302B should be as thin as possible. Ifit is deposited too thick, excess solder paste or epoxy may “squeegee”out the sides from underneath the package and lead to PCB shorts. Suchan issue is especially problematic for dual exposed die pad packages.Minimum distances of 1 mm to 1.5 mm or even greater may be required.

If the epoxy or solder paste layer is sufficiently thin, then solderpaste layer 1302B under the package foot 1305B can be eliminated, as theelectrical connection between foot 1305 and copper trace 1301B can beachieved using the subsequent wave-soldering process. If, however, thelayer of solder paste applied under the exposed die pad 1305A is toothick, then, as shown in top illustration of FIG. 41B, foot 1305B may beseparated from copper trace 1301B by gap 1307. During heating, thepackage may tilt, such that the package and exposed die pad 1305A are nolonger parallel to PCB 1300. The result is that solder paste layer 1302Amelts into a non-uniform wedge of solder 1302Z, making wave-solderingthe foot 1305B to copper trace 1301B difficult. Moreover, foot 1305B mytouch copper trace 1301B at only a single point 1308, making a uniformsolder joint difficult to reproduce consistently.

One solution, shown in the modified USMP fabrication flow chart of FIG.42A, is to insert an extra “solder printing” step (step 1250G) into theprocess flow, between plastic removal (step 1250D) and metal patterningand singulation (step 1250E). While this extra step appears tocomplicate the process, it completely eliminates the need for dual-passPCB assembly. Using this process improvement, any USMP package with anexposed die pad can have an optionally thin solder coating on the bottomside of its feet and the exposed die pad. As shown in the topcross-sectional view of FIG. 42B, a power package with an exposed diepad 1315A is coated with a thin solder layer 1319A, including a thinsolder layer 1319C under die pad-connected foot 1315C and a thin solderlayer 1319B under foot 1315 B. Similarly, as shown in the lowercross-sectional view, in any USMP IC package with an exposed die pad,either dual- or quad-sided, the exposed die pad 1425A is coated with athin solder layer 1329A. Likewise foot 1325C is coated with thin solderlayer 1329C, foot 1325B is coated with thin solder layer 1329B, andother feet (not shown) are also coated with thin solder layers. Thesolder layer may be deposited or printed.

As illustrated in the process flow of FIG. 43A, attaching a powerpackage with exposed die pad 1315A and an USMP footed IC package withexposed die pad 1325A to a PCB can be performed in a single step,bringing them in contact with the PCB and holding them in place to meltthe solder paste, resulting in the structure shown in thecross-sectional view of FIG. 43B, where copper foot 1315B is melted intosolder layer 1319B atop copper trace 1331B atop PCB 1330. After heating,non-power packages, such as a USMP IC package with plastic 1334, areattached by glue or held in position mechanically. Unlike the feet inpower and exposed-die pad packages, copper foot 1335B sits directly atopcopper trace 1331F on PCB 1330, with no intervening solder layer. Afterwave-soldering, as the cross-sectional views of PCB 1330 in FIG. 43Cshow, solder layers now cover all the copper feet, i.e. solder layer1340C covers foot 1315C, solder layer 1340B covers foot 1315B, solderlayer 1340C covers foot 1325C, solder layer 1340E covers foot 1325B, andsolder layer 1340F covers foot 1335B. In this manner, all power andnon-power packages are manufactured in a wave-solder flow without theneed to coat the PCB with solder paste even to assemble the powerdevices.

The left side drawing in FIG. 44A illustrates the underside view of thesolder plated DPAK. The solder paste is printed, with solder paste layer1404C covering exposed die pad 1403 and die-pad attached foot 1402C,with solder paste layer 1404A covering foot 1402A, and with solder pastelayer 1404B covering foot 1402B. After heating the solder paste changesinto solder in the same locations.

In an improved embodiment of a solder-plated USMP package shown in theright side drawing of FIG. 44A, holes 1406 are in included in solderpaste layer 1405C, and solder paste layers 1405A and 1405B are made indonut shapes so that some areas are devoid of solder even after thesolder paste is melted into solder. The purpose of the holes devoid ofsolder is to facilitate locations for test probes to contact the packageduring manufacturing without gumming up the probe tips with solder.

This method is equally applicable for USMP IC packages. As shown in FIG.44B, the package on the left utilizes uniform solder paste layer 1414Con exposed die pad 1413 and uniform solder paste layer 1414A on thepackage's feet 1412. In contrast, the package on the right employsdonut-shaped solder paste layers 1415A on the packages feet 1412 andholes 1416 in the solder paste layer 1415C located on exposed die pad1413.

As illustrated in the cross-sectional view of FIG. 44C, duringmanufacturing electrical tests, probes 1420 are positioned to contactexposed die pad 1403 and foot 1402 through openings 1406 in the solderlayer 1405. In this manner, the probes do not scratch the solder and gumup the probe tips, compromising the probe's ability to achieve a goodelectrical contact to the device under test.

Another consideration in USMP leadframe design specially relates toisolated die pads. As shown in the cross-sectional view of FIG. 45,during wire-bonding of semiconductor die 1459 mounted atop an isolateddie pad 1457 to the cantilever sections 1454A and 1454B connected tofeet 1452A and 1452B, a custom heater block 1460 must be designed toprevented spring board effects and oscillations during the bondingprocess. While customization is possible, another alternative is to fillthe void beneath the isolated die pad with an electrically insulatingthermally conductive compound such as polyamide or epoxy filled withdiamond dust, carbon nanotubes, or ceramic powder. Such a process, whilesimilar to a pre-molded leadframe, does not use the same mold compoundused to form the plastic but instead uses a material optimized for itsgood thermal conduction properties.

The resulting leadframe structures, shown in FIG. 46, comprise thethermal compound 1465 or 1466 permanently affixed to the underside ofthe leadframe during manufacturing and afterwards in the final product.In the top illustration, the thermal compound 1465 is coplanar with thetop surface of isolated die pad 1457 and cantilever sections 1454A and1454C. In the lower illustration, the thermal compound 1466 is coplanarwith the bottom of isolated die pad 1457, and the gaps between the diepad and cantilever sections 1454A and 145B are filled during molding.

The fabrication sequences for the two versions are slightly different.In FIG. 47, the fabrication for the first case is illustrated, where thetop of the leadframe elements 1454A, 1454B, and 1457 are covered with atemporary adhesive layer 1464, e.g., blue tape, before the thermalcompound is 1465 is printed onto the backside of the leadframe. Thethermal compound naturally fills the voids between the die pad 1457 andthe cantilever sections 1454A and 1454B, making it coplanar with the topedge of isolated die pad 1457. After printing, the temporary adhesivelayer 1464 is removed.

In the fabrication sequence of FIG. 48, the backside etch of leadframe1468 is completed, forming a thinned section 1467, shown in the topillustration. Before preforming the frontside etch, however, thermalcompound 1466 is printed or coated into the cavities created by thebackside etch. The frontside etch is then performed, as described above,resulting in the leadframe shown in the bottom illustration, withthermal compound 1466 filling the region beneath isolated die pad 1457.The resulting package offers a benefit of enhanced thermal conductionand lower thermal resistance than conventional isolated die padpackages. Furthermore, the thermally conductive compound providesmechanical support during wire bonding while still allowing a flatheater block to heat the die and leadframe during the wire bondingprocess to improve bonding adhesion. Thus a specialized heater block,such as heater block 1460 shown in FIG. 45, is not required.

Practical examples of USMP Designs As described, the USMP process may beemployed to universally replace any leadless package or any leaded orgull wing package with either a leadless or a footed package equivalentsimply by changing the leadframe design avoiding the need for new orcustom mold tools. The flexibility and universality of the USMP processand design supports any number of manufacturing, design, product, andgo-to-market strategies including,

-   -   Reducing manufacturing cost and improving factory flexibility        and throughput by converting the conventional saw type and punch        type QFN manufacturing to the USMP process, thereby enabling        multiple packages to be fabricated on one common line, i.e.        improving package manufacturing through product line        consolidation,    -   Converting reflow PCB assembly to a lower cost wave solder PCB        assembly by replacing an existing leadless package with a USMP        footed package, using the existing die with no change in the PCB        area or traces, i.e. a cost reduced pin-for-pin replacement,    -   Maintaining the same PCB landing pad locations, design a new        larger die with improved performance, e.g. high current, lower        resistance, more functionality, etc., benefitting from the        improved area efficiency of the USMP made package, i.e. a        performance upgraded pin-for-pin replacement,    -   Shrinking the PCB area, using the existing die package in a more        area efficient USMP made package, i.e. a package shrink,    -   Shrinking the PCB area, using a customized die designed to fit        in a smaller USMP made package, i.e. a die and package shrink,        potentially compatible with a standard PCB trace of a smaller        package, e.g. changing from a 3×3 DFN to a 2×3 DFN.

While, using the USMP manufacturing method, the PCB footprint for footedpackages housing a die originally designed for a leaded package may bemade smaller than their gull-wing equivalents, i.e. the package size maybe reduced, in general it is commercially easier to adopt the fixedpackage footprints of industry-standard conventional packages and thenmaximize the die size. Comparatively, a footed USMP will be slightlyless area-efficient than an etch type QFN or DFN leadless packageoccupying the same PCB space and PCB landing pad layout and slightlymore area-efficient than a punch-type QFN or DFN leadless packageoccupying the same PCB space and PCB landing pad layout butsignificantly more area-efficient than any equivalent leaded, gull-wing,or bent-lead package. In the case of LQFP packages, the footed USMPversion will be substantially more efficient. The definition of the areaefficiency used herein is the maximum die area for a given packagedivided by the PCB area needed to mount the component as defined by thelateral extent of the plastic or the conductors used to mount thecomponent, whichever is larger, i.e. area efficiencyη_(area)=A_(max die)/A_(PCB)

FIG. 49A illustrates an example wherein a saw-type QFN3×3 packageleadframe 1500 is converted into its wave-solder compatible footedequivalent leadframe 1510, whereby die pad 1506 is replaced by die pad1516, leadless landing pads 1502 are replaced with wave solderable feet1512, corner tie bar 1504 is replaced by corner tie bar 1514, andplastic 1501 is replaced by plastic 1511.

The conventional package shown is a saw-type QFN leadless packagebecause a saw, not a mechanical punch, is used to cut the plastic andmetal landing pads to their proper dimensions. As a leadless package,after singulation no metal protrudes past the edge of the plastic, wherethe package's conductive landing pads 1502 are located entirely beneathplastic body 1501. Each conductive landing pad is 0.4 mm long by 0.3 mmwide to enable reliable soldering. The landing pad or “pin” pitch, i.e.the spacing or repeated spacing periodicity of the conductive landingpads, is 0.8 mm. At this pin pitch, a 3 mm by 3 mm quad package contains9 electrical connections, three on each edge. An exposed die pad 1506,held in place by tie bars 1504, can accommodate a maximum die size of1.65 mm by 1.65 mm.

By converting a QFN package into a footed version of a QFN, i.e. a QFF,the USMP process can be used to eliminate the need for solder reflowbased PCB assembly. Using the USMP process to convert a saw type QFNwith leadframe 1520 into the footed QFN shown by leadframe 1530 in FIG.49B without requiring a change in the PCB traces and solder pointsrequires positioning feet 1532 in the same locations where theconventional QFN's landing pads 1522 are located. Feet 1532 must extendpast plastic body 1531 by a distance sufficient to insure good soldercoverage, i.e. the package's “outer lead length”. As described in thecorresponding table, a length of 0.125 mm was chosen as the “outer leadlength”. To maintain compatibility with conventional QFN assembly, feet1532 comprise 0.4 mm-long by 0.3 mm-wide solderable areas, the same as aQFN, except that the feet protrude 0.125 mm beyond the edge of plastic1531 with another 0.275 mm conductive “heel” portion of the foot,remaining beneath the package.

In this manner the footed package shown can be assembled onto a PCBusing either wave-soldering or reflow solder assembly, without requiringany change in the PCB copper traces. Compatibility of the footed packagewith both wave-solder and reflow assembly is another beneficially“universal” aspect of the footed package, uniquely available using USMPdesigns and methods disclosed herein. No other such package is capableof replacing both leaded and leadless packages with the same design.

As mentioned previously, on an area basis the footed QFN is slightlyless area efficient than an equivalently sized saw type QFN package.Because the standard QFN's footprint sets the outer dimension,allocating space for package feet reduces the available area for the diepad. Consequently, the area of exposed die pad 1536 necessarily smallerthan QFN die pad 1526. The resulting footed package has a maximum diesize of only 1.4 mm by 1.4 mm, a reduction of approximately 20% in diearea compared to a saw-type QFN package.

To regain area lost by the solderable feet, a slightly larger package isrequired. For example, increasing the size of 3×3 footed USMP to a 3×4form factor increases the maximum die size to 1.45 mm by 2.1 mm.Although the package is slightly larger, the resulting footed package iswave-solder compatible while the leadless package is not. Moreover, thefooted package is significantly smaller than any wave-solderable leadedpackages capable of packaging comparably sized die.

The same production line used to make a USMP footed package can also beused to fabricate leadless packages. Using the USMP process to convert asaw-type QFN having leadframe 1520 into a USMP-manufactured QFN ofidentical PCB footprint requires no changes in the die, die leadframe orPCB traces. By converting fabrication of a leadless package such as theQFN or DFN from a conventional saw-type singulation to the USMP process,package fabrication of leadless and footed packages can be performed onthe same manufacturing lines without investment in package-specificequipment, specifically, eliminating the need for punch singulationmachine tools and expensive leadframe-specific “machine tool die”. (Themachine tool die is a cutting tool and should not be confused with asemiconductor die). The resulting manufacturing is lower cost and moreflexible. Lacking conductive feet, however, the leadless QFN packagestill requires expensive reflow-based PCB assembly, even using the USMPmanufacturing process.

FIG. 49B illustrates the conversion of a 16-pin saw-type QFN4×4 packageleadframe 1520 into its wave-solder compatible footed equivalentleadframe 1530. The impact of this change to accommodate the foot, isthat plastic body 1521 is reduced slightly in size to form new plasticbody 1531, and corner tie bar 1524 is in the final package shortened insize to form new tie bar 1534, cut by laser to be flush with theexterior surface of the plastic body 1531. Using a foot length of 125 μmand a total foot dimension of 400 μm, the same as a QFN landing padwidth, the table describes that a saw-type QFN is capable of packaging adie up to 2.65 mm by 2.65 mm while the footed version accommodates aslightly smaller maximum die, in this example, 2.4 mm by 2.4 mm,representing a reduction of approximately 18% in die area.

If, however, we compare the 4×4 footed package to the “punch type” QFNleadframe 1540 shown in FIG. 49C, the equivalent area footed package1550 offers a 25% larger die area, i.e. the footed package houses asemiconductor die 125% that of the punch type QFN maximum die size of2.145 mm by 2.145 mm. The punch type QFN 1540 maximum die size issmaller because its conductive landing pads 1542 must extend deeper intothe package than feet 1552 to prevent being ripped from the plastic 1541during punch singulation, a mechanical process which imparts significantstress of the package's plastic and conductors.

The impact of converting a punch type QFN 1549 into an footed package1559 with the same PCB dimensions, is that die pad 1546 increases insize to form larger die pad 1556, plastic body 1541 is increased in sizeto form new plastic body 1551, and corner tie bar 1544 is adjusted insize to form new tie bar 1554, cut by laser to be flush with theexterior surface of the plastic body 1541.

So the footed QFN designed for assembly on a PCB with a 4×4 trace has amaximum die size 18% smaller than a saw type QFN and 25% larger than apunch type QFN as summarized in the table shown in FIG. 49D. Consideringthat the PCB area required for mounting a 4×4 QFN on a PCB is actually4.3 mm by 4.3 mm, the area efficiency η_(area) of the three packages canbe compared directly as 38% for either the saw type QFN or the USMPsingulated QFN, 31% for the QFF (footed QFN), and 28% for the punch typeQFN.

Note that the largest die size and highest area efficiency for a 4×4package, the saw type QFN, can also be fabricated by the USMP processwithout any required change in leadframe design or the manufacturingprocess (except for reprogramming the laser scans). In fact the USMPprocess involving laser metal removal and singulation can be used tointerchangeably manufacture both the USMP leadless QFN44 and the footedQFN44. The footed package nomenclature QFF represents a simplemodification for the acronym QFN meaning “quad flat no-lead” packageinto a QFF meaning “quad flat footed” package.

Another consideration in the leadframe design is the impact of pinpitch, i.e. foot-to-foot spacing on the number of electrical connectionsfor a given package and its effect on PCB assembly. At a pin pitch of0.5 mm, a 4×4 QFN or footed QFN package integrates 24 feet, six on eachside. At small pin pitch dimensions, there is a risk of electricalshorts in a wave-soldering process. The resulting yield loss depends onthe PCB assembly factory and the antiquity of its equipment. As shownpreviously, the same 4×4 package can be adjusted to 0.8 mm pitch as inleadframe 1530, where the number of feet is reduced to 16 in total, fouron each side.

Alternatively, the package can utilize a 0.6 mm pitch resulting in 20feet, five on a side. In extreme cases where very older factories areemployed, the pin pitch can be increased to 1.0 mm with 12 feet, 3 oneach side, or to a pin pitch of 1.27 mm in which case the number of feetis reduced to or 8 feet having 2 on each side. A summary of pin pitchversus number of leads for a 4×4 footed package is shown in table below:

# of Pins Leadless Footed Package Size (Feet) Pin Pitch Name Pkg Name 4mm × 4 mm 24 0.5 mm QFN44-24 QFF44-24 20 0.6 mm QFN44-20 QFF44-20 16 0.8mm QFN44-16 QFF44-16 12 1.0 mm QFN44-12 QFF44-12 8 1.27 mm QFN44-8QFF44-8

As mentioned previously, the leadless package names described aboveapply to either QFN packages fabricated conventionally or using the USMPprocess disclosed herein. The footed package names represent a simplemodification for the terminology QFN meaning “quad flat no-lead” packageinto a QFF meaning “quad flat footed” package.

While the USMP process can be used to fabricate leadless and footed quadpackages, the disclosed method is equally applicable for producingdual-sided packages. FIG. 49E illustrates the conversion of a saw-typeDFN5×6 package leadframe 1560 into its wave-solder compatible footedequivalent leadframe 1570. The impact of replacing leadless landing pads1562 to wave-solder compatible feet 1672, is that plastic body 1561 isreduced slightly in one dimension to form new plastic body 1571, whilein the other dimension the plastic body size does not change so that sawcut tie bar 1564 tie and laser cut bar 1564 remain identical in size.Considering that only one dimension changes, and using a foot length of0.125 mm and a total foot dimension of 0.4 mm, the table reveals thatthe maximum die size of a saw type DFN package is 4.35 mm by 4.55 mm.The footed version, the footed DFN of “DFF” is nearly the same at 4.35mm by 4.30 mm, a reduction of only approximately 6% in die area. Thefooted package is, however, wave-solder compatible while the leadlesspackage is not. Moreover, the USMP process can fabricate both leadlessQFN and footed QFF packages interchangeably even on the samemanufacturing line and equipment.

FIG. 50A illustrates the conversion of a 2-lead DPAK or TO-252 packageleadframe 1580 into its footed equivalent leadframe 1590A. Because ofthe area savings, a substantially larger package is achievable using thefooted package using a 1.6 mm solderable foot length, the maximum diesize of the conventional DPAK 1589 is 3.05 mm by 4.98 mm while thefooted DPAK 1599A can house a die 4.05 mm×4.98 mm or 133% of theconventional maximum die size. To achieve this magnitude of improvementmechanically bent-leads 1582 are replaced by USMP fabricated feet 1592A,the dimension of plastic body 1581 is increased to form elongatedplastic body 1591A, die pad and heat tab 1586 is increased in area toform larger die pad and heat tab 1596A, and mechanically-clipped tie bar1584 protruding from plastic body 1581, is replaced by laser-trimmed tiebar 1594A cut flush with the vertical edge of plastic body 1591A.

In an alternative embodiment of the design, footed DPAK 1590B, shown inFIG. 50B comprises a modification to feet 1592B where the solderableportion of the foot remains 1.6 mm in length but only 0.25 mm of thefoot extends laterally beyond the edge of plastic 1591B. This USMPdesign principle is further elaborated in the perspective views of FIG.50D where conventional DPAK includes mechanically bent leads 1582contacting the PCB for a distance L, in the prior example where L=1.6mm. In design A of the USMP fabricated DPAK 1599A, feet 1592A extendbeyond the vertical edge of plastic 1591 by a full distance of L=1.6 mm,while in design B of the USMP fabricated DPAK 1599B, feet 1592B extendbeyond the vertical edge of plastic 1591 only by a length comprising afraction of the total foot length L, e.g. 0.25 mm to 0.5 mm withremainder of the foot length L remaining under the package and notvisible from above.

The benefit of footed DPAK 1599B design B is that plastic body 1591B isextended allowing die pad and heat tab 1596B to be further expanded,increasing the maximum allowable die size to 5.29 mm×4.98 mm,representing a substantial die size increase, i.e. offering the abilityto package a die over 173% that of a conventional DPAK using the samePCB board space. Tie bar 1594B can also be laser trimmed flush with thevertical face of plastic 1591B, eliminating the unwanted protrusion ofmechanically trimmed tie bar 1584 is conventional DPAK assembly.

A direct comparison of the two USMP footed DPAKs 1599A and 1599B to theconventional DPAK 1589 in FIG. 50C illustrates that in the USMP design,space saved reducing the exterior length ΔY, where ΔY₃<ΔY₂<ΔY₁ is usedto increase area of die pad and tab 1586 to achieve larger area die padand heat tabs 1596A and 1596B. As shown, the length “L” of the copperlead contacting the PCB, remains constant at L=1.6 mm while ΔY, theprotruding length of the lead or the foot, varies from ΔY₃=2.7 mm forthe DPAK to ΔY₂=1.6 mm and ΔY₂=0.25 mm for the footed designs. Soalthough and the positions of the PCB landing pads 1587 and 1597 remainsfixed, the die pad and maximum die size of the package increases. Asanother benefit, in footed DPAKs 1599A and 1599B, tie bars 1594A and1594B can be completely enclosed within plastic body 1591A and plasticbody 1591B respectively, while in the conventional DPAK 1589, tie bar1584 unavoidably protrudes from the package and plastic 1581, increasingthe risk of unwanted and potentially dangerous electrical shorts. Asfurther illustrated in FIG. 50C and FIG. 50D, by avoiding mechanicallead bending the height of footed packages 1599A and 1599B can be madesignificantly thinner, typically 30% to 70% thinner than conventionalDPAK 1589, depending on the thickness of the leadframe and the desiredamount of heat spreading.

A comparison of the conventional DPAK 1589 to design-A footed DPAK 1599Aand design-B footed DPAK 1599B is shown in FIG. 50E. As shown, theUSMP-based packages are able to house maximum die sizes 33% and 74%larger than the conventional DPAK. In USMP manufacturing, singulationuses a laser instead of a mechanical tool, and does not requiremechanical bending or forming. As such USMP-fabricated DPAKs can beproduced in higher-throughput lower-cost matrix leadframes rather onsingle-package strips, reducing costs and improving manufacturability.

FIG. 51A illustrates the conversion of a SOT23 package leadframe 1600into its footed equivalent leadframe 1610 where gull-wing leads 1602A,1602B, and 1602C are replaced by wave-solder compatible feet 1612A, 162Band 1612C, lead extensions 1604 are replaced by cantilever extensions1614, and the size of die pad 1607 is increased substantially to formnew die pad 1617. In the conventional SOT23, isolated die pad 1607connects to lead 1602C, while the other two leads 1602A and 1602Bconnect to isolated lead extensions 1604 for bonding. All the leadscomprise mechanically bent gull wing leads requiring long leadlengths—in fact lead lengths longer than the die pad is wide. Themaximum die size of the conventional SOT23 shown is approximately 0.765mm by 1.706 mm. In sharp contrast to gull wing SOT23, the footed versionshown by matrix leadframe 1610 comprises isolated die pad 1617 connectedto foot 1612C, and two feet 1612A and 16B connected to cantileverextended beams 1614. If desired the beams can be further supported bytie bars (not shown).

By eliminating the wasted space consumed by the gull wing leads, thefooted package allows the plastic and the isolated die pad 1617 toexpand in the direction of the leads, increasing the maximum die size to1.365 mm×1.706 mm, increasing the maximum die size to 178% that ofpresent day SOT23s. A side-by-side comparison of the conventional SOT-231609 and the footed SOT-23 1619 and their corresponding leadframes 1600and 1610 is shown in FIG. 51B illustrating that the PCB area efficiencyof the conventional SOT-23 of only 13% can be improved by the USMPfooted package to 24%, and the footed SOT-23 can house a die 78% largerthan the conventional SOT-23 package.

In addition to offering the ability to improving transistor package areaefficiency, i.e. putting a larger die in the same package, USMP designmethods may also be applied to substantially reduce the size of gullwing IC packages. For example in FIG. 52A a TSSOP-8L package 1649fabricated from leadframe 1640 and comprising dual tie bars 1644, gullwing leads 1642, and isolated die pad 1647, is converted into its footedequivalent package 1659A while preserving the same PCB layout forsoldering. As shown, footed package leadframe 1650A comprises feet1652A, a larger isolated die pad 1657A, and additional tie bars 1654Afor greater stability. By designing the foot for the same solder lengthas the conventional gull wing package, namely 0.6 mm, but eliminatingthe wasted space devoted for lead bending and forming, the maximum diesize of the footed package 1659A increases to 3.8 mm by 2.2 mm, a 49%increase over that of a conventional TSSOP8 maximum die size of 2.8 mmby 2 mm In an alternative embodiment shown in FIG. 52B, the same PCBlayout can be used with footed equivalent package 1659B comprisingleadframe 1650B, feet 1652B, an even larger isolated die pad 1657B, andtie bars 1654B.

FIG. 52C compares the three packages revealing the conventional TSSOP-8Lpackage's PCB area efficiency of 27% can be improved to 40% or 45% usingthe USMP made footed package, with corresponding increases in die sizeof 49% and 69% respectively. In applications such as lithium batteryprotection where this package has become an industry standard, a 49%increase in die area for the same PCB space allows the protective powerMOSFETs either to reduce their on-resistance or power dissipation or toincrease their current rating for the same dissipated power. Theperformance boost is especially beneficial in high-end smart phones withrapid charge capability. The USMP fabricated footed package, also offersan option for either an isolated or exposed die pad providing addedflexibility in thermal management.

In FIG. 53A, the ubiquitous SOP8 package 1669, comprising dual tie bars1664, gull wing leads 1662, and isolated die pad 1666, and fabricatedfrom leadframe 1660, is converted into its footed equivalent package1679A while preserving the same PCB layout for soldering. As shown, thefooted package 1679A, fabricated from leadframe 1670A, comprises feet1672A, a larger isolated die pad 1676A, and additional tie bars 1674Afor greater stability. The isolated die pad 1676A can be replaced withan exposed die pad as required, offering perfect co-planarity becausethe feet and the die pad are made from the same piece of copper. Similarco-planarity is not possible using conventional SOP8 1669 becausemechanical lead bending is intrinsically imprecise. By designing thefoot of the footed package 1679A for the same solder length as theconventional gull wing package 1669, namely 0.6 mm, but eliminating thewasted space devoted for lead bending and forming, the footed package'sdie pad 1676A increases to support a maximum die size of 3.285 mm by4.102 mm, a 96% increase in die area over the 2.213 mm by 3.102 mmmaximum die area of the conventional SOP8 package 1669. The maximum diesize is calculated for an isolated die pad useful for ICs or discretetransistors, not limited only for packaging discrete power MOSFETs.

In an alternative embodiment shown in FIG. 53B, footed package 1679B,fabricated from leadframe 1670B, comprises feet 1672B, a larger isolatedor alternatively an exposed die pad 1676B, and additional tie bars 1674Bfor greater stability. The alternate footed package's die pad 1676Bincreases to support a maximum die size of 3.792 mm by 4.102 mm, a 127%increase in die area over conventional SOP8 1669 This doubling in diearea can be used to accommodate larger ICs with added functionality, orto increase the maximum die size of one or more power MOSFETs to loweron-resistance, reduce heating, improve efficiency or expand the currenthandling capability of a product. A comparison of conventional and USMPfooted SOP8 package performance is summarized in the table of FIG. 53C.

The benefit of the USMP footed package technology becomes mostpronounced in quad-leaded gull wing packages. As shown in FIG. 54A,industry standard and commercially available LQFP package 1709Afabricated from leadframe 1700A and having a 7 mm by 7 mm body, cornertie bars 1704A, gull wing leads 1702A, and isolated die pad 1706A isconverted into its footed equivalent package 1719A while preserving thesame PCB layout for soldering. As shown, footed package 1719A,fabricated from leadframe 1710A, comprises feet 1712A, a larger isolateddie pad 1716A, and corner tie bars 1714A. The isolated die pad can bereplaced with an exposed die pad as required.

By designing the foot for the same solder length as the conventionalgull wing package, namely 0.6 mm, eliminating the wasted space devotedfor lead bending and forming, and optimizing the leadframe, the footedpackage's die pad 1716A increases to support a maximum die size of 6.35mm by 6.35 mm, a die area 318% that of a commercially available LQFP7×7maximum die size of 3.56 mm by 3.56 mm. The larger die area meanssubstantially higher functionality circuitry can now be integrated intowave-solderable packages. The beneficial tripling of area overstates theimprovement achieved by the footed design because conventional leadframe1700A does not illustrate the maximum possible die size. Considering themaximum possible size die pad for a conventional 7×7 LQFP package 1709Bshown in FIG. 54B fabricated from leadframe 1700B, corner tie bars1704B, gull wing leads 1702B, and isolated die pad 1706B, the size ofthe die pad (theoretically) increases to accommodate a maximum die sizeof 4.850 mm by 4.950 mm, nearly double the die size area of commerciallyavailable LQFP 1709A.

For the sake of completeness, in an alternative embodiment of the USMPfabricated footed package the maximum die size is also increased. Alsoshown in FIG. 54B footed package 1719B fabricated from leadframe 1710Band comprising feet 1712B, corner tie bars 1714B, and larger isolateddie pad 1716B is able to increase the maximum die size to 6.750 mm by6.750 mm.

A comparison of the two conventional LQFP packages against their USMPfooted package equivalents is summarized in the table of FIG. 54C, wherehypothetical gull wing LQFP leadframe 1700B is used as a reference, i.e.for a die area ratio defined as 1.00 and having a PCB area efficiency of23%. In contrast, a commercially available 7×7 LQFP leadframe has amaximum die size 48% smaller than optimum and a paltry PCB areaefficiency of only 18%. In contrast, footed replacements for the LQFP,QFF packages with leadframes 1719A and 1719B are capable of maximum diesizes 65% and 85% larger than the maximum die size for the hypotheticalreference LQFP leadframe 1708, and over 200% larger than the maximum diesize for the commercially available 7×7 LQFP packages.

In many cases, when a wave-solderable leaded package is required topackage a die originally developed for a QFN leadless package, there isno area efficient and cost effective package alternative available. Thispoint is illustrated in the following table, where a 2.65 mm by 2.65 mmsemiconductor die designed for a 20-pin QFN needs to be packaged in awave-solderable package. Considering the maximum die size and the numberof pins required for a specific IC, only a few choices exist, many ofwhich are too large or too expensive to meet the design targets of thesystem.

The potential options are summarized in the following table:

PCB Package Maximum Die Pkg Plastic Size Area Cost Conv. 2.65 mm × 2.65mm 4 mm × 4 mm 100% Low QFN44-20 QFF-20 2.65 mm × 2.65 mm 4.25 mm × 4.25mm 113% Low (Footed) TSSOP-20 4.05 mm × 2.85 mm 6.5 mm × 6.4 mm 260% MedSOP-2 2.65 mm × 4.35 m  12.7 mm × 7.8 mm  619% High LQFP55-32 2.3 mm ×2.3 mm 5 mm × 5 mm 156% NA LQFP66 3.0 mm × 3.0 mm 6 mm × 6 mm 225% NALQFP77 3.67 mm × 3.67 mm 7 mm × 7 mm 306% High

While the footed version of the QFN, i.e. the QFF-20, can be used toreplace the conventional package at low cost and in essentially the samePCB area, the TSSOP takes triple the area and the SOP requires six timesthe area. The LQFP55 has acceptable area efficiency except it cannotpackage a 2.65 mm by 2.65 mm die, so it is eliminated as an option. TheLQFP66 is only double the PCB area, but it does not exist in productionand it is unlikely any packaging company will pay the high cost to bringup an obsolete package with a limited market. The result is thecommercially only available LQFP that fits the die is the 7 mm by 7 mmpackage, triple the size of what is needed. Any package more than doublethe size will have too high a cost to support the application.

As a result, the footed package uniquely solves a problem for whichthere are no real solutions available today, offering comparableperformance to leadless packages in a cost effective manner, yetcompatible with low cost wave-solder based PCB assembly.

We claim:
 1. A semiconductor package comprising: a semiconductor dieencapsulated in a plastic body; and at least two metal leads, each ofthe leads being partially encapsulated in the plastic body and having afoot, each of the feet having a flat bottom surface, wherein the flatbottom surfaces of all of the feet are coplanar, wherein the die ismounted on an exposed die pad, the die pad having an exposed flat bottomsurface that is coplanar with the flat bottom surface of each of thefeet, at least a portion of each of the feet being thinner than the diepad.
 2. The semiconductor package of claim 1 wherein at least one of themetal leads is a physical extension of the die pad.
 3. The semiconductorpackage of claim 1 wherein an upper surface of each of the feet islocated at a level below a top surface of the unexposed die pad.
 4. Thesemiconductor package of claim 1 wherein one of the leads comprises alateral extension of the die pad extending outside of the plastic bodyand having at least two thicknesses.
 5. The semiconductor package ofclaim 1 wherein each of the metal leads comprises a vertical columnsegment, a cantilever segment and a foot, a top surface of the verticalcolumn segment being coplanar with a top surface of the cantileversegment, a bottom surface of the vertical column segment being coplanarwith a bottom surface of the foot, wherein at least a part of thecantilever segment is encapsulated in the plastic body.
 6. Thesemiconductor package of claim 5 wherein each of the feet extendsoutside the plastic body.
 7. The semiconductor package of claim 5wherein the die is mounted on a conductive die pad, the die pad having atop surface that is coplanar with the top surface of the cantileversegment.
 8. The semiconductor package of claim 5 wherein the cantileversegment of at least one of the leads is physically connected to theexposed die pad and overlies a portion of the plastic body such that theportion of the plastic body is interposed between the die pad and thevertical column segment of said at least one of the leads, a bottomsurface of the portion of the plastic body being coplanar with thebottom surface of the die pad and the bottom surface of the foot of saidat least one of the leads.
 9. The semiconductor package of claim 5wherein the cantilever segment includes a first portion within theplastic body and a second portion outside of the plastic body.
 10. Asemiconductor package comprising: a die pad at least partiallyencapsulated in a plastic body, the plastic body having a sidewall; ametal lead, the lead protruding through the sidewall to a locationoutside the plastic body; and a tie bar extending laterally from the diepad to the sidewall of the plastic body, an exposed end of the tie barbeing flush with the sidewall.
 11. The semiconductor package of claim 10wherein the sidewall forms a corner of the plastic body with a secondsidewall of the plastic body, the tie bar extending to the corner of theplastic body.
 12. The semiconductor package of claim 10 comprising asecond metal lead, the second metal lead protruding through the sidewallof the package.
 13. The semiconductor package of claim 12 wherein thetie bar is positioned laterally between the lead and the second lead.